IS 1893 ( Part 1 ) :2002

Indian Standard
CRITERIA FOR EARTHQUAKE RESISTANT
DESIGN OF STRUCTURES
PART 1 GENERAL
(

PROVISIONS

Ffth

AND BUILDINGS

Revision )

ICS 91.120.25

0 BIS 2002

BUREAU

OF

INDIAN

STANDARDS

MANAK BHAVAN, 9 BAHADUR SHAH ZAFAR MARG
NEW DELHI 110002
June 2002

—..

Price Group 12

IS 1893( Part 1 ) :2002

Indian Standard
CRITERIA FOR EARTHQUAKE RESISTANT
DESIGN OF STRUCTURES
PART 1 GENERAL
(

PROVISIONS

AND BUILDINGS

Fijth Revision )

FOREWORD
This Indian Standard ( Part 1 ) ( Fifth Revision) was adopted by the Bureau of Indian Standards, afler the
draft finalized by the Earthquake Engineering Sectional Committee had been approved by the Civil Engineering
Division Council.
Himalayan-Nagalushai region, Indo-GangeticPlain, Western India, Kutch and Kathiawarregions are geologically
unstable parts of the country, and some devastating earthquakes of the world have occurred there. A major
part of the peninsular India has also been visited by strong earthquakes, but these were relatively few in
number occurring at much larger time intervals at any site, and had considerably lesser intensity. The earth@ake
resistant design of structures taking into account seismic data from studies of these Indian earthquakes has
become very essential, particularly in view of the intense construction activity all over the country. It is to
serve this purpose that IS 1893 : 1962 ‘Recommendations for earthquake resistant design of structures’ was
published and revised first time in 1966.
As a result of additional seismic data collected in India and further knowledge and experience gained since
the publication of the first revision of this standard, the sectional committee felt the need to revise the standard
again incorporating many changes, such as revision of maps showing seismic zones and epicentres, and adding
a more rational approach for design of buildings and sub-structures of bridges. These were covered in the
second revision of 1S 1893 brought out in 1970.
As a result of the increased use of the standard, considerable amount of suggestions were received for modifying
some of the provisions of the standard and, therefore, third revision of the standard was brought out in 1975.
The following changes were incorporated in the third revision:
a)

The standard incorporated seismic zone factors (previously given as multiplying factors in the second
revision ) on a more rational basis.

b)

Importance factors were introduced to account for the varying degrees of importance for various
structures.

c)

In the clauses for design of multi-storeyed buildings, the coefficient of flexibility was given in the
form of a curve with respect to period of buildings.

d)

A more rational formula was used to combine modal shear forces.

e)

New clauses were introduced for determination of hydrodynamic pressures in elevated tanks.

8

Clauses on concrete and masonry dams were modified, taking into account their dynamic behavionr
during earthquakes. Simplified formulae for design forces were introduced based on results of extensive
studies carried out since second revision of the standard was published.

The fourth revision, brought out in 1984, was prepared to modifi some of the provisions of the standard as a
result of experience gained with the use of the standard. In this revision, a number of important basic modifications
with respect to load factors, field values of N, base shear and modal analysis were introduced. A new concept
of performance factor depending on the structural framing system and on the ductility of construction was
incorporated. Figure 2 for average acceleration spectra was also modified and a curve for zero percent damping
incorporated.

1

IS 1893( Part 1 ) :2002
In the fifth revision, with a view to keep abreast with the rapid development and extensive research that has
been carried out in the field of earthquake resistant design of various structures, the committee has decided
to cover the provisions for different types of structures in separate parts. Hence, IS 1893 has been split into
the following five parts:
Part 1 General provisions and buildings
Part 2 Liquid retaining tanks — Elevated and ground supported
Part 3 Bridges and retaining walls
Part 4 Industrial structures including stack like structures
Part 5 Dams and embankments
Part 1 contains provisions that are general in nature and applicable to all structures. Also, it contains provisions
that are specific to buildings only. Unless stated otherwise, the provisions in Parts 2 to 5 shall be read necessarily
in conjunction with the general provisions in Part 1.
NOTE — Pending finalization of Parts 2 to 5 of IS 1893, provisions of Part 1 will be read along with the relevant
clauses of IS 1893 : 1984 for structures other than buildings.

The following are the major and important moditlcations made in the fifth revision:
a)

The seismic zone map is revised with only four zones, instead of five. Erstwhile Zone I has been
merged to Zone 11. Hence, Zone I does not appear in the new zoning; only Zones II, 111,IV and V do.

b)

The values of seismic zone factors have been changed; these now reflect more realistic values of
effective peak ground acceleration considering Maximum Considered Earthquake ( MCE ) and service
life of structure in each seismic zone.

c)

Response spectra are now specified for three types of founding strata, namely rock and hard soil,
medium soil and soft soil.

d)

Empirical expression for estimating the fundamental natural period Ta of multi-storeyed buildings
with regular moment resisting frames has been revised.

e)

This revision adopts the procedure of first calculating the actual force that maybe experienced by
the structure during the probable maximum earthquake, if it were to remain elastic. Then, the concept
of response reduction due to ductile deformation or frictional energy dissipation in the cracks is
brought into the code explicitly, by introducing the ‘response reduction factor’ in place of the earlier
performance factor.

f)

A lower bound is specified for the design base shear of buildings, based on empirical estimate of the
fimdarnental natural period Ta.

@ The soil-foundation system factor is dropped. Instead, a clause is introduced to restrict the use of
foundations vulnerable to differential settlements in severe seismic zones.
h)

Torsional eccentricity values have been revised upwards in view of serious darnages observed in
buildings with irregular plans.

J)

Modal combination rule in dynamic analysis of buildings has been revised.

k)

Other clauses have been redrafted where necessary for more effective implementation.

It is not intended in this standard to lay down regulation so that no structure shall suffer any damage during
earthquake of all magnitudes. It has been endeavored to ensure that, as far as possible, structures are able
to respond, without structural darnage to shocks of moderate intensities and without total collapse to shocks
of heavy intensities. While this standard is intended for the earthquake resistant design of normal structures,
it has to be emphasized that in the case of special structures, such as large and tall dams, long-span bridges,
major industrial projects, etc, site-specific detailed investigation should be undertaken, unless otherwise specified
in the relevant clauses.

2

IS 1893( Part 1 ): 2002
Though the basis for the design of different types of structures is covered in this standard, it is not implied
that detailed dynamic analysis should be made in every case. In highly seismic areas, construction of a type
which entails hea~y debris and consequent loss of life and property, such as masonry, particularly mud masonry
and rubble masonry, should preferably be avoided. For guidance on precautions to be observed in the construction
of buildings, reference maybe made to IS 4326, IS 13827 and IS 13828.
Earthquake can cause damage not only on account of the shaking which results from them but also due to
other chain effects like landslides, floods, fires and disruption to communication. It is, therefore, important to
take necessary precautions in the siting, planning and design of structures so that they are safe against such
secondary effects also.
The Sectional Committee has appreciated that there cannot bean entirely scientific basis for zoning in view
of the scanty data available. Though the magnitudes of different earthquakes which have occurred in the
past are known to a reasonable degree of accuracy, the intensities of the shocks caused by these earthquakes
have so far been mostly estimated by damage surveys and there is little instrumental evidence to corroborate
the conclusions arrived at. Maximum intensity at different places can be fixed on a scale only on the basis of
the observations made and recorded after the earthquake and thus a zoning map which is based on the maximum
intensities arrived at, is likely to lead in some cases to an incorrect conclusion in view of(a) incorrectness in
the assessment of intensities, (b) human error in judgment during the damage survey, and (c) variation in
quality and design of structures causing variation in type and extent of damage to the structures for the same
intensity of shock. The Sectional Committee has therefore, considered that a rational approach to the problem
would be to arrive at a zoning map based on known magnitudes and the known epicentres ( see Annex A )
assuming all other conditions as being average and to modifi such an idealized isoseismal map in light of
tectonics ( see Annex B ), lithology ( see Annex C ) and the maximum intensities as recorded from damage
surveys. The Committee has also reviewed such a map in the light of the past history and future possibilities
and also attempted to draw the lines demarcating the different zones so as to be clear of important towns,
cities and industrial areas, after making special examination of such cases, as a little modification in the zonal
demarcations may mean considerable difference to the economics of a project in that area. Maps shown in
Fig. 1 and Annexes A, B and C are prepared based on information available upto 1993.
In the seismic zoning map, Zone I and II of the contemporary map have been merged and assigned the level
of Zone 11. The Killari area has been included in Zone III and necessary modifications made, keeping in view
the probabilistic hazard evaluation. The Bellary isolated zone has been removed. The parts of eastern coast
areas have shown similar hazard to that of the Killari area, the level of Zone II has been enhanced to Zone III
and connected with Zone III of Godawari Graben area.
The seismic hazard level with respect to ZPA at 50 percent risk level and 100 years service life goes on
progressively increasing from southern peninsular portion to the Himalayan main seismic source, the revised
seismic zoning map has given status of Zone III to Narmada Tectonic Domain, Mahanandi Graben and Godawari
Graben. This is a logical normalization keeping in view the apprehended higher strain rates in these domains
on geological consideration of higher neotectonic activity recorded in these areas.
Attention is particularly drawn to the fact that the intensity of shock due to an earthquake could vary locally
at anyplace due to variation in soil conditions. Earthquake response of systems would be affected by different
types of foundation system in addition to variation of ground motion due to various types of soils. Considering
the effects in a gross manner, the standard gives guidelines for arriving at design seismic coet%cients based
on stiffness of base soil.
It is important to note that the seismic coefficient, used in the design of any structure, is dependent on nany
variable factors and it is an extremely difficult task to determine the exact seismic coefficient in each given
case. It is, therefore, necessa~ to indicate broadly the seismic coefficients that could generally be adopted
in different parts or zones of the country though, of course, a rigorous analysis considering all the factors
involved has to be made in the case of all important projects in order to arrive at a suitable seismic coeftlcients
for design. The Sectional Committee responsible for the formulation of this standard has attempted to include
a seismic zoning map (see Fig. 1 ) for this purpose. The object of this map is to classifi the area of the country
into a number of zones in which one may reasonably expect earthquake shaking of more or less same maximum
intensity in future. The Intensity as per Comprehensive Intensity Scale ( MSK64 ) ( see Annex D ) broadly
associated with the various zones is VI ( or less ), VII, VIII and IX ( and above ) for Zones II, III, IV and V
respectively. The maximum seismic ground acceleration in each zone cannot be presently predicted with
3

IS 1893( Part 1 ) :2002
accuracy either on a deterministic or on a probabilistic basis. The basic zone factors included herein are
reasonable estimates of effective peak ground accelerations for the design of various structures covered in
this standard. Zone factors for some important towns are given in Annex E.
Base isolation and energy absorbing devices may be used for earthquake resistant design. Only standard
devices having detailed experimental data on the performance should be used. The designer must demonstrate
by detailed analyses that these devices provide sufficient protection to the buildings and equipment as envisaged
in this standard. Performance of locally assembled isolation and energy absorbing devices should be evaluated
experimentally before they are used in practice. Design of buildings and equipment using such device should
be reviewed by the competent authority.
Base isolation systems are found usefhl for short period structures, say less than 0.7s including soil-structure
interaction.
In the formulation of this standard, due weightage has been given to international coordination among the
standards and practices prevailing in different countries in addition to relating it to the practices in the field
in this country. Assistance has particularly been derived from the following publications:
a)

UBC 1994, Uniform Building Code, International Conference of Building Officials, Whittier, Ckdifomia,
U.S.A.1994.

b)

NEHRP 1991, NEHRP Recommended Provisions for the Development of Seismic Regulations for New
Buildings, Part 1: Provisions,ReportNo. FEMA 222, Federal EmergencyManagement Agency,WashingtO%
D.C., U.S.A., January 1992.

c)

NEHRP 1991, NEHRP Recommended Provisions for the Development of Seismic Regulations for New
Buildings, Part 2: Commentary, Report No. FEMA 223, Federal Emergency Management Agency,
Washington, D. C., U. S.A., January 1992.

d) NZS 4203:1992, Code of Practice for General Structural Design and Design Loadings for Buildings,
Standards Association of New Zealand, Wellington, New Zealand, 1992.
In the preparation of this standard considerable assistance has been given by the Department of Earthquake
Engineering, University of Roorkee; Indian Institute of Technology, Kanpuq IIT Bombay, Mumbai; Geological
Survey of India; India Meteorological Department, and several other organizations.
The units used with the items covered by the symbols shall be consistent throughout this standard, unless
specifically noted otherwise.
The composition of the Committee responsible for the formulation of this standard is given in Annex F.
For the purpose of deciding whether a particular requirement of this standard is complied with, the final value
observed or calculated, expressing the result of a test or analysis, shall be rounded off in accordance with
IS 2:1960 ‘Rules for rounding off numerical values ( revised )’. The number of signflcant places retained in
the rounded off value should be the same as that of the specified value in this standard.

(Earthquake Engineering Sectional Committee, CED 39 )
4

As in the Original Standard, this Page is Intentionally Left Blank

IS 1893( Part 1 ): 2002

Indian Standard
CRITERIA FOR EARTHQUAKE RESISTANT
DESIGN OF STRUCTURES
PART 1 GENERAL

PROVISIONS

( Ffth

AND BUILDINGS

Revision )
Title

IS No.

1 SCOPE
1.1 This standard ( Part 1 ) deals with assessment of
seismic loads on various structures and earthquake
resistant design of buildings. Its basic provisions
are applicable to buildings; elevated structures;
industrial and stack like structures; bridges; concrete
masonry and earth dams; embankments and retaining
walls and other structures.

1343:1980

Code of practice for pre-stressed
concrete (first revision )

1498:1970

Classification and identification of
soils for general engineering
purposes (first revision )

1888:1982

Method of load test on soils (second
revision

)

1.2 Temporary elements such as scaffolding, temponuy
excavations need not be designed for earthquake
forces.

1893 (Part4)

1.3 This standard does not deal with the construction
features relating to earthquake resistant design in
buildings and other structures. For guidance on
earthquake resistant construction of buildings,
reference may be made to the following Indian
Standards:

Criteria for earthquake resistant
design of structures: Part 4 Industrial
structures including stack like
structures

2131:1981

Method of standard penetration test
for soils (first revision )

2809:1972

Glossary of terms and symbols
relating to soil engineering ( jirst

IS 4326,1S 13827, IS 13828,IS 13920and IS 13935.

revision )

2 REFERENCES
2.1 The following Indian Standards are necessary
adjuncts to this standard:
Is No.

456:2000

Code of practice for plain and
( fourth
reinforced
concrete

4326:1993

Earthquake resistant design and
construction of buildings — Code
of practice ( second revision )

6403:1981

Code of practice for determination
of bearing capacity of shallow
foundations (first revision )

13827:1993

Improving earthquake resistance of
earthen buildings — Guidelines

13828:1993

Improving earthquake resistance of
low strength masonry buildings —
Guidelines

13920:1993

Ductile detailing of reinforced
concrete structures subjected to
seismic forces — Code of practice

13935:1993

Repair and seismic strengthening of
buildings — Guidelines

SP 6 ( 6 ) :1972

Handbook for structural engineers:
Application of plastic theory in
design of steel structures

)

Code of practice for general
construction in steel ( second
revision )

875

Glossary of terms relating to soil
dynamics (fzrst revision)

Title

revision

800:1984

2810:1979

Code of practice for design loads
( other than earthquake ) for buildings
and structures:

(Part l): 1987 Dead loads — Unit weights of
building material and storedmaterials
( second revision)
(Part 2):1987

Imposed loads ( second revision)

(Part 3):1987

Wind loads ( second revision)

(Part4 ):1987

Snow loads ( second revision)

(Part 5):1987

Special loads and load combinations
( second revision)
7

PrT-’!?

IS 1893( Part

) :2002

3.11 Effective Peak Ground Acceleration ( EPGA )

3 TERMINOLOGY FOR EARTHQUAKE

ENGINEERING

It is O.4 times the 5 percent damped average spectral
acceleration between period 0.1 to 0.3 s. This shall
be taken as Zero Period Acceleration ( ZPA ).

3.1 For the purpose of this standard, the following
definitions shall apply which are applicable generally
to all structures.

3.12 Floor Response Spectra

NOTE — For the definitions of terms pertaining to soil
mechanics and soil dynamics references may be made
to IS 2809 and IS 2810.

3.2 Closely-Spaced

Floor response spectra is the response spectra for a
time history motion of a floor. This floor motion time
history is obtained by an analysis of multi-storey
building for appropriate material damping values
subjected to a specified earthquake motion at the base
of structure.

Modes

Closely-spaced modes of a structure are those of its
natural modes of vibration whose natural frequencies
differ from each other by 10 percent or less of the
lower frequency.

3.13 Focus
The originating earthquake source of the elastic waves
inside the earth which cause shaking of ground due
to earthquake.

3.3 Critical Damping
The damping beyond which the free vibration motion
will not be oscillatory.

3.14 Importance Factor (1)
It is a factor used to obtain the design seismic force
depending on the functional use of the structure,
characterised by hazardous consequences of its failure,
its post-earthquake functional need, historic value,
or economic importance.

3.4 Damping
The effect of internal friction, imperfect elasticity of
material, slipping, sliding, etc in reducing the amplitude
of vibration and is expressed as a percentage of critical
damping.
3.5 Design Acceleration

3.15 Intensity of Earthquake

Spectrum

The intensity of an earthquake at a place is a measure
of the strength of shaking during the earthquake, and
is indicated by a number according to the modified
Mercalli Scale or M. S.K. Scale of seismic intensities
(see AnnexD ).

Design acceleration spectrum refers to an average
smoothened plot of maximum acceleration as a fimction
of frequency or time period of vibration for a specitled
damping ratio for earthquake excitations at the base
of a single degree of freedom system.
3.6 Design Basis Earthquake

3.16 Liquefaction

( DBE )

Liquefaction is a state in saturated cohesionless soil
wherein the effective shear strength is reduced to
negligible value for all engineering purpose due to
pore pressure caused by vibrations during an
earthquake when they approach the total confining
pressure. In this condition the soil tends to behave
like a fluid mass.

It is the earthquake which can reasonably be expected
to occur at least once during the design life of the
structure.
3.7 Design Horizontal

Acceleration

Coefficient

(Ah)

3.17 Lithological

It is a horizontal acceleration coefficient that shall be
used for design of structures.
3.8 Design Lateral

Features

The nature of the geological formation of the earths
crust above bed rock on the basis of such characteristics
as colour, structure, mineralogical composition and
grain size.

Force

It is the horizontal seismic force prescribed by this
standard, that shall be used to design a structure.

3.18 MagnitudeofEarthquake

( Richter% Magnitude)

3.9 Ductility
The magnitude of earthquake is a number, which is a
measure of energy released in an earthquake. It is
defined as logarithm to the base 10 of the maximum
trace amplitude, expressed in microns, which the
standard short-period torsion seismometer ( with a
period of 0.8s, magnification 2800 and damping nemly
critical ) would register due to the earthquake at an
epicentral distance of 100 km.

Ductility of a structure, or its members, is the capacity
to undergo large inelastic deformations without
significant loss of strength or stiffness.
3.10 Epicentre
The geographical point on the surface of earth vertically
above the focus of the earthquake.
8

IS 1893( Part 1 ) :2002
idealized single degree freedom systems having certain
period and damping, during earthquake ground
motion. The maximum response is plotted against the
undamped natural period and for various damping
values, and can be expressed in terms of maximum
absolute acceleration, maximum relative velocity, or
maximum relative displacement.

3.19 Maximum Considered Earthquake ( MCE )
The most severe earthquake effects considered by
this standard.
3.20 Modal Mass ( lf~ )
Modal mass of a structure subjected to horizontal or
vertical, as the case maybe, ground motion is apart
of the total seismic mass of the structure that is effective
in mode k of vibration. The modal mass for a given
mode has a unique value irrespective of scaling of
the mode shape.
3.21 Modal Participation

3.28 Seismic Mass
It is the seismic weight divided by acceleration due
to gravity.
3.29 Seismic Weight (W)

Factor ( Pk)

It is the total dead load plus appropriate amounts of
specified imposed load.

Modal participation factor of mode k of vibration is
the amount by which mode k contributes to the overall
vibration of the structure under horizontal and vertical
earthquake ground motions. Since the amplitudes of
95 percent mode shapes can be scaled arbitrarily, the
value of this factor depends on the scaling used for
mode shapes.

3.30 Structural

Response Factors ( S,/g )

It is a factor denoting the acceleration response
spectrum of the structure subjected to earthquake
ground vibrations, and depends on natural period
of vibration and damping of the structure.

3.22 Modes of Vibration ( see Normal Mode)

3.31 Tectonic Features

3.23 Mode Shape Coefficient ( $i~)
When a system is vibrating in normal mode k, at any
particular instant of time, the amplitude of mass
i expressed as a ratio of the amplitude of one of the
masses of the system, is known as mode shape
coefficient ( @i~).

The nature of geological formation of the bedrock in
the earth’s crust revealing regions characterized by
structural features, such as dislocation, distortion,
faults, folding, thrusts, volcanoes with their age of
formation, which are directly involved in the earth
movement or quake resulting
in the above
consequences.

3.24 Natural Period (T)

3.32 Time History Analysis

Natural period of a structure is its time period of
undamped free vibration.

It is an analysis of the dynamic respmse of the structure
at each increment of time, when its base is subjected
to a specific ground motion time history.

3.24,1 Fundamental

Natural

Period ( T1)

3.33 Zone Factor (Z)
It is the first ( longest ) modal time period of vibration.

It is a factor to obtain the design spectrum depending
on the perceived maximum seismic risk characterized
by Maximum Considered Earthquake ( MCE ) in the
zone in which the structure is located. The basic zone
fiwtorsincluded in this standard are reasonable estimate
of effective peak ground acceleration.

3.24.2 Modal Natural Period ( T~)
The modal natural period of mode k is the time period
of vibration in mode k.
3.25 Normal Mode

3.34 Zero Period Acceleration ( ZPA )

A system is said to be vibrating in a normal mode when
all its masses attain maximum values of displacements
and rotations simultaneously, and pass through
equilibrium positions simultaneously.

It is the value of acceleration response spectrum for
period below 0.03 s ( frequencies above 33 Hz).
-,.
4 TERMINOLOGY FOR EARTHQUAKE
ENGINEERING OF BUILDINGS

3.26 Response Reduction Factor (R)
It is the factor by which the actual base shear force,
that would be generated if the structure were to remain
elastic during its response to the Design Basis
Earthquake ( DBE ) shaking, shall be reduced to obtain
the design lateral force.
3.27 Response

4.1 For the purpose of earthquake resistant design
ofbuildings in this standard, the following definitions
shall apply.
4.2 Base
It is the level at which inertia forces generated in the
strnctnre are transferred to the foundation, which then
transfers these forces to the ground.

Spectrum

The representation

of the maximum response of
9

IS 1893( Part 1 ) :2002
4.3 Base Dimensions (d)

4.14 Lateral Force Resisting Element

Base dimension of the building along a direction is
the dimension at its base, in metre, along that direction.

It is part of the structural system assigned to resist
lateral forces.

4.4 Centre of Mass

4.15 Moment-Resisting Frame

The point through which the resultant of the masses
of a system acts. This point corresponds to the centre
of gravity of masses of system.

It is a frame in which members and joints are capable
of resisting forces primarily by flexure.
4.15.1 Ordinary

4.5 Centre of Stiffness

Moment-Resisting

Frame

It is a moment-resisting frame not meeting special
detailing requirements for ductile behaviour.

The point through which the resultant of the restoring
forces of a system acts.

4.15.2 Special Moment-Resisting

Frame

It is the value of eccentricity to be used at floor i in
torsion calculations for design.

It is a moment-resisting frame specially detailed
to provide ductile behaviour and comply with
the requirements given in IS 4326 or IS 13920 or
SP6(6).

4.7 Design Seismic Base Shear ( V~)

4.16 Number of Storeys ( n )

It is the total design lateral force at the base of a
structure.

Number of storeys of a building isthe number of levels
above the base. This excludes the basement storeys,
where basement walls are connected with the ground
floor deck or fitted between the building columns. But,
it includes the basement storeys, when they are not
so connected.

4.6 Design Eccentricity

( e~i)

4.8 Diaphragm
It is a horizontal, or nearly horizontal system, which
transmits lateral forces to the vertical resisting elements,
for example, reinforced concrete floors and horizontal
bracing systems.

4.17 Principal Axes
Principal axes of a building are generally two mutually
perpendicular horizontal directions inphmof abuilding
along which the geometry of the building is oriented.

4.9 Dual System
Buildings with dual system consist of shear walls
( or braced frames ) and moment resisting frames such
that:
a)

The two systems are designed to resist the
total design lateral force in proportion to their
lateral stiffness considering the interaction
of the dual system at all floor levels; and

b)

The moment resisting frames are designed
to independently resist at least 25 percent
of the design base shear.

4.18 P-A Effect
It is the secondary effect on shears and moments of
frame members due to action of the vertical loads,
interacting with the lateral displacement of building
resulting from seismic for~es.
4.19 Shear Wall
It is a wall designed to resist lateral forces acting in
its own plane.
4.20 Soft Storey

4.10 Height of Floor ( hi )

It is one in which the lateral stiffness is less than
70 percent of that in the storey above or less than
80 percent of the average lateral stiffness of the three
storeys above.

It is the difference in levels between the base of the
building and that of floor i.
4.11 Height of Structure(k)

4.21 Static Eccentricity

It is the difference in levels, in metres, between its
base and its highest level.

( e~l)

It is the distance between centre of mass and centre
of rigidity of floor i.

4.12 Horizontal Bracing System
It is a horizontal truss system that serves the same
function as a diaphragm.

4.22 Storey

4.13 Joint

4.23 Storey Drift

It is the portion of the column that is common to other
members, for example, beams, framing into it.

It is the displacement of one level relative to the other
level above or below.

It is the space between two adjacent floors.

10

IS 1893( Part 1 ) :2002
4.24 Storey Shear ( ~)

n

Number of storeys

It is the sum of design lateral forces at all levels above
the storey under consideration.

N

SPT value for soil

Pk

Modal participation factor of mode k

Q,

Lateral force at floor i

Q~~

Design lateral force at floor i in mode k

r

Number of modes to be considered as per
7.8.4.2

R

Response reduction factor

4.25 Weak Storey
It is one in which the storey lateral strength is less
than 80 percent of that in the storey above, The storey
lateral strength is the total strength of all seismic force
resisting elements sharing the storey shear in the
considered direction.
5 SYMBOLS

S’a/g Average response acceleration coefficient

The symbols and notations given below apply to the
provisions of this standard:
.4h

Design horizontal seismic coefficient

A~

Design horizontal acceleration spectrum
value for mode “kof vibration

bi

ith Floor plan dimension of the building
perpendicular to the direction of force

c

Index for the closely-spaced modes

d

Base dimension of the building, in metres,
in the direction in which the seismic force
is considered.

DL

Response quantity due to dead load

‘dl

Design eccentricity to be used at floor i
calculated as per 7.8.2

e

S1

for rock or soil sites as given by Fig. 2
and Table 3 based on appropriate natural
periods and damping of the structure

Static eccentricity at floor i defined as the
distance between centre of mass and centre
of rigidity

T

Undamped natural period of vibration of
the structure (in second )

~

Approximate
seconds )

Tk

Undamped natural period of mode k of
vibration (in second )

T1

Fundamental natural period of vibration
(in second )

VB

Design seismic base shear

pB

Design base shear calculated using the
approximate fimdamental period T,

q

Peak storey shear force in storey i due to
all modes considered

qk

Shear force in storey i in mode k

fundamental

period ( in

Response quantity due to earthquake load
for horizontal shaking along x-direction

v roof Peak storey shear force at the roof due to

ELY

Response quantity due to earthquake load
for horizontal shaking along y-direction

w

Seismic weight of the structure

Wi

Seismic weight of floor i

EL,

Response quantity due to earthquake load
for vertical shaking along z-direction

z

Zone factor

ELX

all modes considered

Oik

Froof Design lateral forces at the roof due to all

modes considered
Fi

Design lateral forces at the floor i due to
all modes considered

$?

Acceleration due to gravity

h

Height of structure, in metres

hi

Height measured from the base of the
building to floor i

I

Importance factor

IL

Response quantity due to imposed load

h4k

Modal mass of mode k

Mode shape coet%cient at floor i in mode
k

11

a

Peak response (for example member forces,
displacements, storey forces, storey shears
or base reactions ) due to all modes
considered

%

Absolute value of maximum response in
mode k

kc

Absolute value of maximum response in
mode c, where mode c is a closely-spaced
mode.

A*

Peak response due to the closely-spaced
modes only

IS 1893( Part 1 ) :2002
Pij

oi

for this difference in actual and design lateral loads.

Coefficient used in the Complete Quadratic
Combination ( CQC ) method while
combining responses of modes i andj

Reinforced and prestressed concrete members shall
be suitably designed to ensure that premature failure
due to shear or bond does not occur, subject to the
provisions of IS 456 and IS 1343. Provisions for
appropriate ductile detailing of reinforced concrete
members are given in IS 13920,

Circular frequency in rad/second in the
iti mode

6 GENERAL PRINCIPLES AND DESIGN
CRITERIA

In steel structures, members and their connections
should be so proportioned that high ductility is obtain~
tide SP 6 ( Part 6 ), avoiding premature failure due to
elastic or inelastic buckling of any type.

6.1 General Principles
6.1.1 Ground

Motion

The characteristics ( intensity, duratio~ etc ) of seismic
ground vibrations expected at any location depends
upon the magnitude of earthquake, its depth of focus,
distance from the epicentre, characteristics of the path
through which the seismic waves travel, and the soil
strata on which the structure stands. The random
earthquake ground motions, which cause the structure
to vibrate, can be resolved in any three mutually
perpendicular directions. The predominant direction
of ground vibration is usually horizontal.

The specified earthquake loads are based upon postelastic energy dissipation in the structure and because
of this fact, the provision of this standard for design,
detailing and construction shall be satisfied even for
structures and members for which load combinations
that do not contain the earthquake effect indicate larger
demands than combinations including earthquake.
6.1.4 Soil-Structure

Interaction

The soil-structure interaction refers to the effects of
the supporting foundation medium on the motion of
structure. The soil-structure interaction may not be
considered in the seismic analysis for structures
supported on rock or rock-like material.

Earthquake-generated vertical inertia forces are to be
considered in design unless checked and proven by
specimen calculations to be not significant. Vertical
acceleration should be considered in structures with
large spans, those in which stability is a criterion for
design, or for overall stability analysis of structures.
Reduction in gravity force due to vertical component
of ground motions can be particularly detrimental in
cases of prestressed horizontal members and of
cantilevered members. Hence, special attention should
be paid to the effect of vertical component of the ground
motion on prestressed or cantilevered beams, girders
and slabs.

6.1.5 The design lateral force specified in this standard
shall be considered in each of the two orthogonal
horizontal directions of the structure. For structures
which have lateral force resisting elements in the two
orthogonal directions only, the design lateral force
shall be considered along one direction at a time, and
not in both directions simultaneously. Structures,
having lateral force resisting elements (for example
frames, shear walls ) in directions other than the two
orthogonal directions, shall be analysed considering
the load combinations specified in 6.3.2.

6.1.2 The response of a structure to ground vibrations
is a fimction of the nature of foundation soil; materials,
form, size and mode of construction of structures;
and the duration and characteristics of ground motion.
This standard specifies design forces for structures
standing on rocks or soils which do not settle, liquefi
or slide due to loss of strength during ground vibrations.

Where both horizontal and vertical seismic forces are
taken into account, load combinations specified
in 6.3.3 shall be considered.
6.1.6 Equipment and other systems, which are
supported at various floor levels of the structure, will
be subjected to motions corresponding to vibration
at their support points. In important cases, it may be
necessary to obtain floor response spectra for design
of equipment supports. For detail reference be made
to IS 1893 (Part 4).

6.1.3 The design approach adopted in this standard
is to ensure that structures possess at least a minimum
strength to withstand minor earthquakes ( <DBE ),
which occur frequently, without damage; resist
moderate earthquakes ( DBE ) without significant
structural damage though some non-structural damage
may OCCUE
and aims that structures withstand a major
earthquake ( MCE ) without collapse, Actual forces
that appear on structures during earthquakes are much
greater than the design forces speciiled in this standard.
However, ductility, arising from inelastic material
behaviourand detailing, and overstrength, arising from
the additional reserve strength in structures over and
above the design strength, are relied upon to account

6.1.7 Additions

to Existing Structures

Additions shall be made to existing structures only
as follows:
a)

12

An addition that is structurally independent
from an existing structures shall be designed
and constructed in accordance with the
seismic requirements for new structures.

IS 1893( Part 1 ): 2002
b)

these shall be combined as per 6.3.1.1 and 6.3.1.2
where the terms DL, IL and EL stand for the response
quantities due to dead load, imposed load and
designated earthquake load respectively.

An addition
that is not structurally
independent from an existing structure shall
be designed and constructed such that
the entire structure conforms to the seismic
force resistance requirements
for new
structures
unless the following three
conditions are complied with:

6.3.1.1

3)

for plastic

design

of steel

In the plastic design of steel structures, the following
load combinations shall be accounted for:

1) The addition shall comply with the
requirements for new structures,
2)

Load factors

structures

The addition shall not increase the seismic
forces in any structural elements of the
existing structure by more than 5 percent
unless the capacity of the element
subject to the increased force is still in
compliance with this standard, and

1)

1.7( DL.+IL )

2)

1.7( DL*EL)

3)

1.3( DL+lL*EL)

6.3.1.2 Partial safety factors for limit state design
of reinforced concrete and prestressed
concrete
structures

The additicn shall not decrease the
seismic resistance of any structural
element of the existing structure unless
reduced resistance is equal to or greater
than that required for new structures.

In the limit state design of reinforced and prestressed
concrete structures, the following load combinations
shall be accounted for:

6.1.8 Change in Occupancy

1)

1.5( DL+lL)

When a change of occupancy results in a structure
being re-classified to a higher importance factor ( 1 ),
the structure shall conform to the seismic requirements
for anew structure with the higher importance factor.

2)

1.2( DL+ZL+EL)

3)

1.5( DL+EL)

4)

0.9DL* 1.5EL

6.2 Assumptions

6.3.2 Design Horizontal

The following assumptions shall be made in the
earthquake resistant design of structures:

When the lateral load resisting elements are
oriented along orthogonal horizontal direction, the
structure shall be designed for the effects due to till
design earthquake load in one horizontal direction at
time.

a)

6.3.2.2 When the lateral load resisting elements are
not oriented along the orthogonal horizontal directions,
the stmcture shall be designed for the effects due to
foil design earthquake load in one horizontal direction
plus 30 percent of the design earthquake load in the
other direction.

NOTE — However, there are exceptions where
resonance-like conditions have been seen to occur
between long distance waves and tall structures
founded on deep soft soils.

Earthquake
is not likely to occur
simultaneously with wind or maximum flood
or maximum sea waves,

c)

The value of elastic modulus of materials,
wherever required, may be taken as for static
analysis unless a more definite value is
available for use in such condition ( see
IS 456, IS 1343 and IS 800 )

Load

6.3.2.1

Earthquake causes impulsive ground motions,
which are complex and irregular in character,
changing in period and amplitude each lasting
for a small duration. Therefore, resonance of
the type as visualized under steady-state
sinusoidal excitations, will not occur as it
would need time to buildup such amplitudes.

b)

Earthquake

NOTE — For instance, the building should be designed
for ( + ELx i 0.3 EL.y ) as well as ( * 0.3 ELx * ELy ),
where x and y are two orthogonal horizontal directions,
EL in 6.3.1.1 and 6.3.1,2 shall be replaced by ( ELx i
0.3 ELy ) or ( ELy i 0.3 .!Lh ).

6.3.3 Design Vertical Earthquake

Load

When effects due to vertical earthquake loads are to
be considered, the design vertical force shall be
calculated in accordance with 6.4.5.
6.3.4

Combination

for Two or Three Component

6.3 Load Combination and Increase in Permissible
Stresses

Motion

6.3.1 Load Combinations

When responses from the three earthquake
components are to be considered, the responses due
to each component may be combined using the
6.3.4.1

When earthquake forces are considered on a structure,
13

IS 1893( Part 1 ) :2002
Zones III, IV, V and less than 10 in seismic Zone II,
the vibration caused by earthquake may cause
liquefaction or excessive total and differential
settlements. Such sites should preferably be avoided
while locating new settlements or important projects.
Otherwise, this aspect of the problem needs to be
investigated and appropriate methods of compaction
or stabilization adopted to achieve suitable N-values
as indicated in Note 3 under Table 1. Alternatively,
deep pile foundation may be provided and taken to
depths well into the layer which is not likely to liquefi.
Marine clays and other sensitive clays are also known
to lique~ due to collapse of soil structure and will
need special treatment according to site condition.

assumption that when the maximum response from
one component occurs, the responses from the other
two component are 30 percent of their maximum. All
possible combinations of the three components ( ELx,
ELy and ELz ) including variations in sign ( plus or
minus ) shall be considered, Thus, the response due
earthquake force (EL ) is the maximum of the following
three cases:
1) %ELX*O.3 ELyho.3ELz
2) *ELy*O.3 ELx&O.3 ELz
3)

*ELz*

0.3 ELx&O.3 ELy

where x and y are two orthogonal directions and z is
vertical direction.

NOTE — Specialist literature may be referred
determining liquefaction potential of a site.

6.3.4.2 As an alternative to the procedure in 6.3.4.1,
the response (EL ) due to the combined effect of the
three components can be obtained on the basis of
‘square root of the sum of the square ( SRS S )‘ that
is
EL = ~ (ELx)2+

6.4

Design Spectrum

6.4.1 For the purpose of determining seismic forces,
the country is classified into four seismic zones as
shown in Fig. 1.

(ELy)z+(ELz)2

6.4.2 The design horizontal seismic coefficient Ah
for a structure shall be determined by the following
expression:

NOTE — The combination procedure of 6.3.4.1 and
6.3.4.2 apply to the same response quantity (say, moment
in a column about its major axis, or storey shear in a
frame) due to different components of the ground motion.

.zIsa
Ah=—

6.3.4.3 When two component motions ( say one

2Rg

horizontal and one vertical, or only two horizontal)
are combined, the equations in 6.3.4.1 and 6.3.4.2
should be modified by del >ting the term representing
the response due to the component of motion not being
considered.
6.3.5 Increase in Permissible

for

Provided that for any structure with T <0.1 s, the
value of A~will not be taken less than Z/2 whatever
be the value of I/R
where

Stresses

z.

When earthquake forces are considered along with
other normal design forces, the permissible stresses
in material, in the elastic method of design, maybe
increased by one-third. However, for steels having a
definite yield stress, the stress be limited to the yield
stress; for steels without a definite yield point, the
stress will be limited to 80 percent of the ultimate
strength or 0.2 percent proof stress, whichever is
smaller; and that in prestressed concrete members,
the tensile stre’ssin the extreme fibers of the concrete
may be permitted so as not to exceed two-thirds of
the modulus of rupture of concrete.

Zone factor given in Table 2, is for the
Maximum Considered Earthquake ( MCE )
and service life of structure in a zone. The
factor 2 in the denominator of Z is used so
as to reduce the Maximum Considered
Earthquake ( MCE ) zone factor to the fktor
for Design Basis Earthquake ( DBE ).

z=

Importance factor, depending upon the
functional
use of the structures,
characterised by.hazardous consequences
of its failure, post-earthquake functional
needs, historical value, or economic
importance ( Table 6 ).

6.3.5.2 Increase

R=

Response reduction factor, depending on
the perceived seismic damage performance
of the structure, characterised by ductile
or brittle deformations. However, the ratio
(I/R ) shall not be greater than 1.0( Table
7). The values of R for buildings are given
in Table 7.

6.3.5.1

Increase impermissible

in allowable

stresses in materials

pressure

in soils

When earthquake forces are included, the allowable
bearing pressure in soils shall be increased as per
Table 1, depending upon type of foundation of the
structure and the type of soil.
In soil deposits consisting of submerged loose sands
and soils falling under classification
SP with
standard penetration N-values less than 15 in seismic

S’a/g = Average response acceleration coefficient
14

IS 1893( Part 1 ): 2002
Table 1 Percentage of Permissible Increase in Allowable Bearing Pressure or Resistance of Soils
(L’lause 6.3.5.2)
Foundation

S1 No.

Type of Soil Mainly Constituting
the
A
r
Type I Rock or Hard Soil : Type H Medium S&ls :
Well graded gravel and sand All soils with N between 10
gravel mixtures with or and 30, and poorly graded
without clay binder, and sands or gravelly sands with
clayey sands poorly graded little or no fines ( SP1~)
or sand clay mixtures ( GB, with N> 15
CW, SB, SW, and SC )1)
having )@ above 30, where
N is the standard penetration
value

Foundation
>
Type III Soft Soils: AU
soils other than SP’J
with N< 10

(1)

(2)

(3)

(4)

(5)

1)

Piles passing through any
soil but resting on soil type I

50

50

50

ii)

Piles not covered
item i

25

25

iii)

Raft foundations

50

50

50

iv)

Combined isolated RCC
footing with tie beams

50

25

25

v)

Isolated RCC footing without
tie beams, or unreinforced
strip foundations

50

25

—

vi)

Well foundations

50

25

25

under

NOTES
1 The allowable bearing pressure shall be determined in accordance with IS 6403 or IS 1888.
2 If any increase in bearing pressure has already been permitted for forces other than seismic forces, the total increase
in allowable bearing pressure when seismic force is also included shall not exceed the limits specified above.
3 Desirable minimum field values of N — If soils of smaller N-values are met, compacting may be adopted to achieve
these values or deep pile foundations going to stronger strata should be used.
4 The values of N ( corrected values ) are at the founding level and the allowable bearing pressure shall be determined in
accordance with IS 6403 or IS 1888.
,
Seismic Zone
Depth Below Ground
N-Values
Remark
level (in metres )
III, IV and V

11 ( for important
structures only )

<5

15

> lo

25

<5
> Ir)

20

15

For values of depths between 5 m and
10 m, linear
interpolation
is
recommended

5 The piles should be designed for lateral loads neglecting lateral resistance of soil layers liable to liquefy.
6 IS 1498 and IS 2131 may also be referred.
7 Isolated R, C.C. footing without tie beams, or unreinforced strip foundation shall not be permitted in soft soils with
N<1O.
1) See IS 1498.
2)

See IS 2131.

15

IS-1893 ( Part 1 ) :2002
for rock or soil sites as given by Fig. 2 and
Table 3 based on appropriate natural periods
and damping of the structure. These curves
represent free tleld ground motion.

foundations placed between the ground level and
30 m depth, the design horizontal acceleration spectrum
value shall be linearly interpolated between Ah and
0.5 Ah, where Ah is as specified in 6.4.2.

NOTE — For various types of structures, the
values of Importance Factor I, Response Reduction
Factor R, and damping values are given in the
respective parts of this standard. The method
( empirical or otherwise ) to calculate the natural
periods of the structure to be adopted for evaluating
S,/g is sdso given in the respective parts of this
standard.

6.4.5 The design acceleration spectrum for vertical
motions, when required, may be taken as two-thirds
of the design horizontal acceleration spectrum specitled
in 6.4.2.
Figure 2 shows the proposed 5 percent spectra for
rocky and soils sites and Table 3 gives the multiplying
factors for obtaining spectral values for various other
clampings.

Table 2 Zone Factor, Z
( Clause 6.4.2)
Seismic
Zone

II

Seismic
Intensity

Low

0.10

z

For rocky, or hard soil sites

Iv

v

Moderate

Severe

Very
Severe

0.16

0,24

0.36

111

s,
g
-1

r

2.50

O.1O<T<O.4O

l.00/T

0.40< TS4.00

1+15~

O.OO<TSO.1O

2.50

O.1O<T<O.55

I 1.361T

0.55 sT<4.00

s
~
g

=

For soft soil sites

6.4.4 For underground structures and foundations
at depths of 30 m or below, the design horizontal
acceleration spectrum value shall be taken as half the
value obtained from 6.4.2. For structures and

1

0.00< Ts”o.lo

For medium soil sites

6.4.3 Where a number of modes are to be considered
for dynamic analysis, the value of Ah as defined
in 6.4.2 for each mode shall be determined using the
natural period of vibration of that mode.

3.0

=

1+15~

1+15Z

Sa
=

T

r

r

I

0.00 S T<O.1O

2.50

0.10 S TsO.67

1 1.67/T

0.67 ST<4.00

,

,

Type 1 (Rock, or Hard So
2.5
T

.....‘,
‘, ,.
‘! ,,
\ ‘.

Type II (Medium Soil)
h

/Tv~e II1(Soft Soil)

2.0

1.5

1.0

0.5

—

-----------

--.--.--:.. ........
---------—

0.0
0.0

0.5

1.0

1“5

2’0

2“5

3“0

3“5

Period(s)

Fm.

2 RESPONSE
SPECTRA
~R ROCKANDSOILSITESFOR5 PERC~ DAMPM
16

4“0

IS 1893( Part 1 ): 2002
and 6.3.1.2 where the gravity loads are combined with
the earthquake loads [ that is, in load combinations
(3) in 6.3.1.1, and (2) in 6.3.1.2 ]. No further reduction
in the imposed load will be used as envisaged in
IS 875( Part 2 ) for number of storeys above the one
under consideration or for large spans of beams or
floors.

6.4.6 In case design spectrum is specifically prepared
for a structure at a particular project site, the same
may be used for design at the discretion of the project
authorities

7 BUILDINGS
7.1 Regular and Irregular

Configuration

7.3.4 The proportions of imposed load indicated above
for calculating the lateral design forces for earthquakes
are applicable to average conditions. Where the
probable loads at the time of earthquake are more
accurately assessed, the designer may alter the
proportions indicated or even replace the entire
imposed load proportions by the actual assessed load.
In such cases, where the imposed load is not assessed
as per 7.3.1 and 7.3.2 only that part of imposed load,
which possesses mass, shall be considered. Lateral
design force for earthquakes shall not be calculated
on contribution of impact effects from imposed loads.

To perform well in an earthquake, a building should
possess four main attributes, namely simple and regular
cotilguration, and adequate lateral strength, stiffness
and ductility. Buildings having simple regolar geomet~
and uniformly distributed mass and stiffness in plan
as well as in elevation, suffer much less damage than
buildings with irregular configurations. A building
shall be considered as irregular for the purposes of
this standard, if at least one of the conditions given
in Tables 4 and 5 is applicable,
7.2 Importance
FactorR

Factor Zand Response Reduction

7.3.5 Other loads apart from those given above ( for
example snow and permanent equipment ) shall be
considered as appropriate.

The minimum value of importanm factor,1, for ditlerent
building systems shall be as given in Table 6. The
response reduction factor, R, for different building
systems shall be as given in Table 7.

7.4 Seismic Weight
7.4.1 Seismic

7.3 Design Imposed Loads for Earthquakes Force
Calculation

Weight of Floors

The seismic weight of each floor is its full dead load
plus appropriate amount of imposed load, as specified
in 7.3.1 and 7.3.2. While computing the seismic weight
of each floor, the weight of columns and walls in any
storey shall be equally distributed to the floors above
and below the storey.

loading classes as specified in
7.3.1 For various
IS 875( Part 2 ), the earthquake force shall be calculatcxl
for the full dead load plus the percentage of imposed
load as given in Table 8.

7.4.2 Seismic Weight of Building

7.3.2 For calculating the design seismic forces of the
structure, the imposed load on roof need not be
considered.

The seismic

7.3.3 The percentage of imposed loads given in 7.3.1
and 7.3.2 shall also be used for ‘Whole frame loaded’
condition in the load combinations specified in 6.3. L 1

7.4.3 Any weight supported in between storeys shall
be distributed to the floors above and below in inverse
proportion to its distance from the floors.

weight

of the whole building

is the sum

of the seismic weights of all the floors.

Table 3 Multiplying Factors for Obtaining Values for Other Damping
( Clause 6.4.2)
Damping,
percent
Factors

o

2

5

7

10

15

20

25

30

3.20

1,40

1.00

0.90

0.80

0.70

0,60

0.55

0.50

17

IS 1893( Part 1 ) :2002
Table 5 — Concluded

Table 4 Definitions of Irregular Buildings —
Plan Irregularities ( Fig. 3 )

Irregularity

S1 No.

( Clause 7.1 )

Type and Description
(2)

(1)
S1 No.

Irregularity

Type and Description

i)

ii)

(2)

(1)

Mass irregularity shall be considered to exist where
the seismic weight of any storey is more than 200
percent of that of its adjacent storeys. The irregularity
need not be considered in case of roofs

Torsion Irregularity
To be considered when floor diaphragms are rigid
in their own plan in relation to the vertical structural
elements that resist the lateral forces. Torsional
irregularity to be considered to exist when the
maximum storey drift, computed with design
eccentricity, at one end of the structures transverse
to an axis is more than 1.2 times the average of
the storey drifts at the two ends of the structure

ii)

Vertical Geometric Irregularity

iii)

Vertical geometric irregularity shall be considered
to exist where the horizontal dimension of the lateral
force resisting system in any storey is more than
150 percent of that in its adjacent storey

Re-en?rant Corners

iv)

Plan configurations of a structure and its lateral
force resisting system contain re-entrant corners,
where both projections of the structure beyond the
re-entrant corner are greater than 15 percent of
its plan dimension in the given direction
iii)

Mass Irregulari@

In-Plane Discontinuity in VerticalElenrentsResisttng
Lateral Force
A in-plane offset of the lateral force resisting
elements greater than the length of those elements
Discontinuity in CapaciQ — Weak Strorey

v)

A weak storey is one in which the storey lateral
strength is less than 80 percent of that in the storey
above, The storey lateral strength is the total
strength of all seismic force resisting elements
sharing the storey shear in the considered direction.

Diaphragm Discontinuity
Diaphragms with abrupt discontinuities or variations
in stiffness, including those having cut-out or open
areas greater than 50 percent of the gross enclosed
diaphragm area, or changes in effective diaphragm
stiffness of more than 50 percent from one storey
to the next

iv)

Table 6 Importance Factors, 1

Out-of-Plane Offsets

( Clause 6.4.2)

Discontinuities in a lateral force resistance path,
such as out-of-plane offsets of vertical elements
v)

S1 No.

Strue tur e

(1)

(2)

i)

Important service and community
buildings, such as hospitals; schools;
monumental structures; emergency
buildings like telephone exchange,
television stations, radio stations,
railway stations, fire station buildings;
large community halls like cinemas,
assembly halls and subway stations,
power stations

Non-parallel Systems
The vertical elements resisting the lateral force
are not parallel to or symmetric about the major
orthogonal axes or the lateral force resisting elements

Table 5 Definition of Irregular Buildings —
Vertical Irregularities ( Fig. 4 )
( Clause 7.1 )
S1 No.
(1)
i)

Irregularity

Type and Description
(2)

ii)

a) Stiffness Irregularity — Soft Storey

AU other buildings

Importance
Factor
(3)

1.5

1.0

NOTES

A soft storey is one in which the lateral stiffness
is less than 70 percent of that in the storey above
or less than 80 percent of the average lateral stiffness
of the three storeys above

1 The design engineer may choose values of importance
factor I greater than those mentioned above.
2 Buildings not covered in SI No. (i) and (ii) above may
be designed for higher value ofZ, depending on economy,
strategy considerations like multi-storey buildings having
several residential units.

b) Stiffness Irregularity — Extreme Soft Storey
A extreme soft storey is one in which the lateral
stiffness is less than 60 percent of that in the storey
above or less than 70 percent of the average stiffness
of the three storeys above. For example, buildings
on STILTS will fall under this category,

3 This does not apply to temporary structures
excavations, scaffolding etc of short duration.

18

like

IS 1893 (Part 1 ): 2002

I

\

I
\

i,

/
\l

i

.

VERTICAL
COMPONENTS
OF
SEISMIC
RESISTING
SYSTEM

—-——

--

—..

—.——

FLOOR
i
i
I

Al
J_

I

Az

+-----------+f
3 ATorsional Irregularity

-r

I

A\ L> O-15-0,20

IL-r

L

‘7

7

L2

A2

Al

3 B Re-entrant Corner
FIG. 3 PLAN IRREGULARITIES
— Continued

19

IS 1893( Part 1 ) :2002
MASS

RESISTANCE

ECCENTRICITY

m“m
VERTICAL

COMPONENTS
OF
SYSTEM

E

SEISMIC

RESISTING

OPENING

FLOOR

3 C Diaphragm Discontinuity

+--SHEAR
WALL

/////////

///,’//

BUILDING

o
D

///////

SECTION

WALLS

3 D Out-of-Plane Offsets

EE3
BUILDING

PLAN

3 E Non-Parallel System
FIG. 3 PLAN IRREGULARITIES

20

---------------.------Eli
E13
Elii
EE!l
IS 1893( Part 1 ) :2002

STOREY STIFFNESS
FOR THE BUILDING
kn
#

kn-l

SOFT
ki<

kn-2

B

STOREY

OR ki<08

k3

WHEN

0.7 kl+l
(

ki+l

+ki+2

+ki+s

3

~
1

kz
k,
H //

/

4 A Stiffness Irregularity

SEISMIC
WEIGHT
Wn
w n-l
n-2

B

W2
mw

MASS
WHEN,
OR

4 B Mass Irregularity
FIG. 4 VERTICALIRREGULARITIES
— Continued

21

IRREGULARITY
Wt >20
Wi>

Wi_l

20 Wl+l

IS 1893( Part 1 ): 2002

Q&j
A

A

AIL>O-10

AIL >0-15

ALA

b

4 C Vertical Geometric Iregularity

when L2 >1.5 L,

STOREY STRENGTH
(LATERAL)
Fn

B.

Fn.l

Fn.2

.
4 E weak Storey when ~ c 0,8 ~ + 1

4 D In-Plane Discontinuity in Vertical Elements Resisting
Lateral Force when b > a

FIG.4 VEKHCALIRREGULAIUHSS

22

IS 1893( Part 1 ): 2002
Table 7 Response Reduction Factor l), R, for Building Systems

.

( Clause 6.4.2)
Lateral

S1 No.

Load Resisting

R

System

(3)

(2)

(1)
Building Frame Systems
i)

4

Ordinary RC moment-resisting

ii)

Special RC moment-resisting

iii)

Steel frame with

iv)

3.0

frame ( OMRF )2)

5.0

frame ( SMRF )3)
.

a) Concentric braces

4.0

b) Eccentric braces

5.0
5.0

Steel moment resisting frame designed as per SP 6 ( 6 )
Building with Shear Walls4~

v)

Load bearing masonry wall buildings)
a) Unreinforced

1.5

b) Reinforced with horizontal RC bands

2.5

c) Reinforced with horizontal RC bands and vertical bars at corners of rooms and
jambs of openings

3.0

vi)

Ordinary reinforced concrete shear walls@

3.0

vii)

Ductile shear walls7)

4.0”

Buildings with Dual Systemss)
viii)

Ordinary shear wall with OMRF

3.0

ix)

Ordinary shear wall with SMRF

4,0

x)

Ductile shear wall with OMRF

4.5

xi)

Ductile shear wall with SMRF

5.0

0 The va]ues of response riduction fact&s are to be used for buildings with lateral load resisting elements, and not Just
for the lateral load resisting elements built in isolation.
2) OMRF

are those designed

and

detailedas per IS 456 or Is 800” but not

meeting

ductile detailing

reqllirertlellt
M

per IS 13920 or SP 6 (6) respectively.
b

3)

SMRF defined in 4.15.2.

4) Buildings

with shear walls also include buildings having shear walls and frames, but where:

a) frames are not designed to carry lateral loads, or
b) frames are designed to carry lateral loads but do not fulfil the requirements of ‘dual systems’.
5)

Reinforcement

6)

Prohibited in zones IV and V.

n

Ductile shear walls are those designed and detailed as per IS 13920.

s)

Buildings with dual systems consist of shear walls ( or braced frames ) and moment resisting frames such that:

should be as per IS 4326.

a) the two systems are designed to resist the total design force in proportion to their lateral stiffness considering
the interaction of the dual system at all floor levels,; and
b) the moment resisting frames are designed to independently resist at least 25 percent of the design seismic base
shear,

.23

,,

,

IS 1893( Part 1 ): 2002
7.6.2 The approximate fundamental natural period
of vibration ( T, ), in seconds, of all other buildings,
including moment-resisting fimne buildings with brick
intil panels, may be estimated by the empirical
expression:

Table 8 Percentage of Imposed Load to be
Considered in Seismic Weight Calculation
7.3.1 )

(Clause
Imposed Uniformity
Distributed Floor
Loads ( kN/ mz )

Percentage

of Imposed
Load

0.09
‘=

(1)

(2)

Upto and including 3.0

25

Above 3.0

50

m

where
h=

Height ofbuilding, inw as defined in7.6.l;
and

d=

7.5 Design Lateral Force

7.5.1 Buildings and portionsthereof shall be designed
and constructed, to resist the effects of design lateral
force specified in 7.5.3 as a minimum.

Base dimension of the building at the plinth
level, in m, along the considered direction
of the lateral force.
.

7.7 Distribution

of Design Force

7.7.1 Vertical Distribution
Floor LeveLr

7.5.2 The design lateral force shall first be computed
for the building as a whole. This design lateral force
shall then be distributed to the various floor levels.
The overall design seismic force thus obtained at each
floor level, shall thenbe distributed to individual lateral
load resisting elements depending on the floor
diaphragm action.

of Base Shear to Differmt

The design base shear ( V~ ) computed in 7.5.3 shall
be distributed along the height of the building as per
the following expression:
W h,z

l’

Qi=J’B.

7.5.3 Design Seismic Base Shear
where

The total design lateral force or design seismic base
shear ( VB) along any principal direction shall
be determined by the following expression:

Qi = Design lateral force at floor i,
Wi = Seismic weight of floor i,

V~ = AhW

hi = Height of floor i measured from base, and

where
n

Ah = Design horizontal acceleration spectrum
value as per 6.4.2, using the fundamental
natural period T,as per 7.6 in the considered
direction of vibration, and

.

Number of storeys in the building is the
number of levels at which the masses are
located.

7.7.2 Distribution of Horizontal Design Lateral Force
to Different Lateral Force Resisting

w.

Seismic weight of the building as per 7.4.2.

7.6.1 The approximate fundamental natural period
of vibration ( T, ), in seconds, of a moment-resisting
frame building without brick in.fd panels may be
estimated by the empirical expression:

= 0.085 h075

7.7.2.2 In case of building whose floor diaphragms
can not be treated as infinitely rigid in their own plane,
the lateral shear at each floor shall be distributed to
the vertical elements resisting the lateral forces,
considering the in-plane flexibility of the diaphragms.

for RC frame building
for steel frame building

where
h

=

Elements

7.7.2.1 In case of buildings whose floors are capable
of providing rigid horizontal diaphragm action, the
total shear in any horizontal plane shall be distributed
to the various vertieal elements of lateral force resisting
system, assuming the floors to be infinitely rigid in
the horizontal plane.

7.6 Fundamental Natural Period

T. = 0,075 h07s

*

Height of building, in m. This excludes
the basement storeys, where basement walls
are connected with the ground floor deck
or fitted between the building columns.
But it includes the basement storeys, when
they are not so connected.

NOTES
1 A floor diaphragm shaJl be considered to be flexible,
if it deforms such that the maximum lateral displacement
measured from the chord of the deformed shape at
any point of the diaphragm is more than 1.5 times the
average displacement of the entire diaphragm.
24

.

IS 1893( Part 1 ): 2002
building shall be petiormed as per established methods
of mechanics using the appropriatemasses and elastic
stiffness of the structural system, to obtain natural
periods (T) and mode shapes {$} of those of its modes
of vibration that need to be considered as per 7.8.4.2.

2 Reinforced concrete monolithic slab-beam floors or
those consisting of prefabricated/precast elements with
topping reinforced screed can be taken a rigid diaphragms.

7.8 Dynamic Analysis
7.8.1 Dynamic analysis shall be pefiormed to obtain
the design seismic force, andits distributionto different
levels along the height of the building andtothevarious
lateral load resisting elements, for the following
buildings:

7.8.4.2 Modes to be considered
The number of modes to be used in the analysis should
be such that the sum total of modal masses of all modes
considered is at least 90 percent of the total seismic
mass and missing mass correction beyond 33 percent.
If modes with natural frequency beyond33 Hz are to
be considered, modal combination shall be carried out
only for modes upto 33 Hz. The effect of higher modes
shall be included by considering missing mass
correction following well established procedures.

a) Regular buildings — Those greater than
40 m in height in Zones IV and ~ and those
greater than 90 m in height in Zones II and
111. Modelling as per 7.8.4.5 can be used.
b) irregular buildings ( as defined in 7.1 ) —
Allfiamedbuildingshigherthan12minZones
IVand~andthosegreaterthan40minheight
in Zones 11and III.

7.8.4.3 Analysis

of building

subjected

to design

forces

The analyticalmo&l fordynamicanalysisof buildings
with unusual configuration should be such that it
adequately models the types of irregularities present
in the building configuration. Buildings with plan
irregularities,as defimedin Table4 ( as per 7.1 ), cannot
be modelled for dynamic analysis by the method given
in 7.8.4.5.

The building may be analyzed by accepted principles
of mechanics for the design forces considered as static
forces.
7.8.4.4 Modal combination
The peak response quantities ( for example, member
forces, displacements, storey forces, storey shears
and base reactions ) shall be combined as per Complete
Quadratic Combination ( CQC ) method.

NOTE — For irregular buildings, lesser than 40 m in
height in Zones 11and III, dynamic anrdysis, even though
not mandatory, is recommended.
7.8.2

Dynamic

by the

Time

Spectrum

analysis
History

Method.

may be performed

Method
However,

in either

design base shear ( VB) shall be compared
shmr ( J?B) calculated using a fundamental
where

either

I

or by the Response
method,

,,

the

with abase
period T,,

where

T, is as per 7.6. Where t’~is less than ~~, all

the response quantities (for example member forces,
displacements, storey forces, storey shears and base
reactions) shall be multiplied by ~~ / V~.

r

. Number of modes being considered,

pij

=

Cross-modal coeffkient,

7.8.2.1 The value of damping for buildings maybe
takenas 2 and 5 percentof the critical, forthe purposes
of dynamic analysis of steel and reinforced concrete
buildings, respectively.

Ai

=

Response quantity in mode i ( including
sign ),

Lj = Response quantity in mode j ( including
sign ),

7.8.3 Time History Method

8&(l+J3)~15

Time history method of analysis, when used, shall
be based on an appropriate ground motion and shall
be performed using accepted principles of dynamics.
‘7.8.4 Response

pij

(l+p2)2+452p(

7.8.4.1 Free Ebration

Analysis

free vibration

l+/.3)2

~=

Modal damping ratio (in ffaction) as
specified in 7.8.2.1,

p=

Frequency ratio = O,/(oi,

0.),=

Circular frequeney in ith mode, and

(l)j=

Circular frequeney injth mode.

Spectrum Method

Response spectrum method of analysis shall be
performed using the design spectrum specified in 6.4.2,
or by a site-specific design spectrum mentioned
in 6.4.6.

Undamped

=

Alternatively, the peak response quantities may be
combined as follows:

analysis of the entire
25

.’

IS 1893 (
a)

Part 1 ) : 20{)2

If the building
modes,

then

c)

does not have closely-spaced
the

( k ) due to all

peak

response

quantity

modes considered shall be

obtained as

Design Lateral Force at Each Floor in Each
Mode — The peak lateral force ( Qi~) at floor
i in mode k is given by

Q,k = .4k ~,~‘k ‘,
where
.4k = Design’ horizontal
acceleration
spectrum value as per 6.4.’2 using
the natural period of vibration ( Tk)
of mode k.

k~ = Absolute value of quantity in mode k, and
r
b)

d) Storey Shear Forcev in Each Mode — The
peak shear force ( P’,k) acting in storey i in
mode k is given by

= Number of modes being considered
If the building has a few closely-spaced modes
( see 3.2), then the peak response quantity
( k“ ) due to these modes shall be obtained
as

&
j=l+l

e)

f)

~orces

at Each

Con,videred

Storey

Due

to .411

—

F,,,,,f = I;,,(,f, and
* [/;– J.:+,

F,

7.9 Torsion
.!

7.9.1 Provision shall be made jn all buildings for.
increase in shear forces on.the lateral force resisting
elements resulting from the horizontal torsional moment
arising due to eccentricity between the centre of mass
and centre of rigidity. The design forces calculated
as in 7,8.4.5 are to be applied at the centre of nl~s
appropriately displaced so as to cause design
eccentricity ( 7.9.2 ) between the displaced centre of,
mass and centre of rigidity. However, negative torsional
shear shall be neglected.

The mockdmass ( M~) of mode

●

7.9.2 The design eccentricity, e~ito
-. be used at floor

where

i shall be taken as:

= Acceleration due to gravity,

1.5e,, + 0,05 b,

$i~ = Mode shape coefficient at floor J in
mode k, and

‘dl

=

,1

or

e,i –

0.05 bi

whichever of these gives the more severe effect n
the shear of any ’frame where

Py = Seismic weight of floor i.
b)

Lateral

The design lateral
forces, F,,,,,f and F,, at roof and at floor i :

k is given by

~

Shear Forcetv due to .411 A40dev
C’onividered — The peak storey shear force

Mode,v

7.8.4.5 Buildings with regular, or nominally irregyla~{
plan configurations may be modelled as a system of
nm.ses lumped at the floor levels with each mass having
one degree of freedom, that of lateral displacement
in the direction under consideration. In such a case;
the following expressions shall hold in the computation
of the various quantities : “
A40dalA4ass —

Storey

( Vi) in storey i due to all modes considered
is obtained by combining those due to each
mode in accordarice with 7:8.4.4.

where the summation is for the closely-spaced modes
only This peak response quantity due to the closely
spaced modes ( L“ ) is then combined with those of
the remaining well-separated modes by the method
described in 7.8.4.4 (a).

a)

,

Participation
Factors
— The
modal participation factor ( P~ ) of mode k is
given by:

Modal

‘dl =

Static eccentricity at floor i defined as the
distance between centre of mass and centre
of rigidity, and

b,

Floor plan dimension
of floor i,
perpendicular to the direction of force.

n

x

‘, @,k

=

NOTE — The

factor 1.5 represents
dynamic
amplification factor, while the factor 0,05 represents
the extent of accidental eccentricity.

,=1

26

.

IS 1893( Part 1 ) :2002
direction under consideration, do not lose their vertical
load-carrying capacity under the induced moments
resulting from storey deformations equal to R times
the storey displacements calculated as per 7.11.1.
where R is specified in Table 7.

7.9.3 In case of highly irregular buildings analyzed
to 7.8.4”.5, additive shears will be
according
superimposed for a statically applied eccentricity of
+ ().()5b, with respect to the centre of rigidity

Buildings with Soft Storey

7.10
7.10.1

In case buildings

as the ground

storey

with a flexible

consisting

parking that is Stilt buildings,
to be made to increase
of the soft/open

of open spaces

special arrangement

the lateral strength

NOTE — For instauce, cnnsider a flat-slab building in
which lateral Inad resistance is provided by shear walls.
Since the Isstersdload resistance rfthe slab-column system
is small. these are nften designed nnly for the gravity
loads, while all the seismic force is resisted by the shear
walls. Even thnugh the slabs and columns are not required
to share the lateral forces, these det-orm with rest ot’
the structure. under seismic force, The concern is tbtit
under such detbrmations, the slab-column system should
not lose its vertical Iuad capucity.

storey, such
for

needs

and stiffness

storey.

7.10.2 Dynamic analysis of building is carried out
including the strength and stiffness effects of infills
and inelastic deformations in the members, particularly,
those in the soft storey, and the members designed
accordingly,

7.10.3 Alternatively,
to be adopted

after

the following
carrying

7.11.3 Separation
same building

design criteria are

7.11

with separatiolljoint

in between

shall

times
the sum of the calculated storey displacements as per
7.11.1 of each of them, to avoid damaging con~act
when the two units deflect towards each other. When
floor levels of two similar adjacent units or buildings
are at the same elevation levels, factor R in this
requirement may be replaced by R/2.

out the earthquake

7.12 Miscellaneous

besides the columns designed and detailed
for the calculated storey shears and moments,
shear walls placed symmetrically in both
directions of the building as far away from
the centre of the building as feasible; to be
designed exclusively for 1.5 times the lateral
storey shear force calculated as before,

7.12.1

Foundations

The use of foundations vulnerable to significant
differential settlement due to ground shaking shall
be avoided for structures in seismic Zones III, IV and
V In seismic Zones IV and V,individual spread footings
or pile caps shall be interconnected
with ties,
( .~ee5.3.4.1 of 1S4326 ) except when individual spread
footings are directly supported on rock. All ties shall
be capable of carrying, in tension and in compression,
an axial force equal to .4, /4 times the larger of the

Deformations

7.11.1

[Jnits

be separated by a distance equal to the amount R

the columns and beams of the soft storey are
to be designed for 2.5 times the storey shears
and moments calculated under seismic loads
specified in the other relevant clauses: or.

b)

.4djacent

Two adjacent buildings. or two adjacent units of the

analysis, neglecting the effect of infill walls in other
storeys:
a)

Between

Store,v Drift Limitation

,1

The storey
specified

drift
design

in any storey
lateral

column

due to the minimum

force, with partial

computed

load factor

or pile cap load, in addition
forces,

of 1,(). shall not exceed O.()()4 times the storey height,

7.12.2

For the purposes
( see 7.11.1,7.11.2

7.12.2.1 Wrtica[ projection,r

of displacement
requirements
only
and 7.11.3 only), it is permissible

limit on design

seismic

force specified

There shall be no drift limit for single storey building
which has been designed
7.11.2 Defer-mation
A~enlhers

to accommodate

Conlpatibility

Cantilever

Projectioniv

Tower, tanks, parapets, smoke stacks ( chimneys)
and other vertical cantilever projections attached to
buildings and projecting above the roof, shall be
designed and checked for stability for five times the
design horizontal seismic coefficient Ah specified
in 6.4.2. In the analysis of the building, the weight
of these projecting elements will be lumped with the
roof weight.

to use seismic force obtained
from the computed
fundamental
period (7’) of the building without the
lower bound
in 7.8.2.

to the otherwise

Here, i4h is as per 6.4.2.

storey drift.

of Non-Se isnlic

7.12.2.2

Horizontal

projection

All horizontal projections like cornices and balconies
shall be designed and checked for stability for
five times the design vertical coefficient specified

For building located in seismic Zones IV and ~ it shall
be ensured that the structural components, that are
not a part of the seismic force resisting system in the
27

IS 1893( Part 1 ): 2002
in 6.4.5 (that is = 10/3 A~).

7.12.4 Connections

7.12.2.3 The increased design forces specified
in 7.12.2.1 and 7.12.2.2 are only for designing the
projecting parts and their connections with the main
structures. For the design of the main structure,such
increase need not be considered.

All partsof the building, exceptbetween the separation
sections, shall be tied together to act as integrated
single unit. All connections between different parts,
such as beams to columns and columns to their
footings, should be made capable of transmitting
a force, in all possible directions, of magnitude
( Qi/wi) times but not less t&m 0.05 times the weight
of the smaller part or the total of dead and imposed
load reaction. Frictional resistance shall not be relied
upon for fulfilling these requirements.

7.12.3 Compound

Walls

Compound walls shall be designed for the design
horizontal coeftlcient Ah with importance factor
1= 1.0 specified in 6.4.2.

Between Parts

.

.

28

1S 1893 ( Part 1 ) :2002

ANNEX A
( Foreword)
68°

72°

AND SURROUNDING

SHOWING
8

EPICENTRES

,,~

‘

48o
KILOMETRES

32°

c
o

n-o

V&,

~

~’p

n

~

RA?PUR

20

2

o

1

16’

1

12“

8°

@ Government

of India, Copyright

Year 2001.

Based upon Survey of India map with the permission of the Surveyor General of India.
The responsibility

for the correctness

of internal details rests with the publisher.

The territorial waters of India extend into the sea to distance of twelve nautical miles measured from the appropriate
The administrative

headquarters

of Chandigarh,

Haryana and Punjab are at Chandigarh.

The interstate boundaries between Arunachal Pradesh, Assam and Meghalaya shown on this map are as interpreted
North-Eastern Areas (Reorganization) Act, 1971, but have yet to be verified.
The external boundaries

base line.

and coastlines of India agree with the Record/Maater
29

Copy certified by Survay of India.

from the

1

As in the Original Standard, this Page is Intentionally Left Blank

A..>..

IS 1893( Part 1 ): 2002

ANNEX D
(

Foreword

and Clause

3.15 )

COMPREHENSIVE INTENSITY SCALE ( MSK 64 )
d) Intensity

The scale was discussed generally at the intergovermnental meeting convened by UNESCO in April
1964. Though not finally approved the scale is more
comprehensive
and describes the intensity of
earthquake more precisely. The main definitions used
are followings;
a)

Tvpe of Structures

(Buildings)

Type.4 —

Building in field-stone, rural
unburnt-brick
structures,
houses, clay houses.

Tvpe B —

Ordinary brick buildings,
buildings of large block and
prefabricated type, half timbered
structures, buildings in natural
hewn stone,

Tvpe C —

Reinforced buildings, well built
wooden structures,

b) Definition

c)

Most

About 75 percent

Cla.~~iflcation

of Danlage to Buildings

Fine cracks in plaster:
fall of small pieces of
plaster.

Grade 1 Slight damage

Grade 2 Moderate damage

Small cracks in plaster:
fall of fairly large pieces
of plaster: pantiles slip
off cracks in chimneys
parts of chimney fall
down,

Grade 3 Hea%ydamage

Large and deep cracks
in plaster:
fall of
chimneys,

Grade 4 Destruction

Gaps in walls: parts of
buildings may collapse:
separate parts of the
buildings lose their
cohesion: and inner
walls collapse,

Sca~e(y noticeable (very slight) — Vibration

3.

Weak, partially
observed
only — The
earthquake is felt indoors by a few people,
outdoors only in favorable circumstances.
The vibration is like that due to the passing
of a light truck. Attentive observers notice
a slight swinging of hanging objects.
somewhat more heavily on upper floors.

4.

Largelv ob.verved — The earthquake is felt

i)

The earthquake is felt indoors by all,
outdoors by many. Many people awake.
A few run outdoors. Animals become
uneasy. Building tremble throughout.
Hanging objects swing consider~bly.
Pictures knock against walls or swing out
of place. Occasionally pendulum clocks
stop. Unstable objects overturn or shift.
Open doors and windows are thrust open
and slam back again. Liquids spill in small
amounts from well-filled open containers.
The sensation of vibration is like that
due to heavy objects falling inside the
buildipgs.

ii) Slight damages in buildings of Type A
are possible.
iii) Sometimes changes in flow of springs.
33

.

2.

5. Awakening

Total collapse of the
buildings.

Grade 5 Total damage

Not noticeable
— The intensity of the
vibration is below the limits of sensibility:
the tremor is detected and recorded by
seismograph only.

indoors by many people, outdoors by few.
Here and there people awake, but no one is
frightened. The vibration is like that due to
the passing of a heavily loaded truck.
Windows, doors, and dishes rattle. Floors
and walls crack. Furniture begins to shake.
Hanging objects swing slightly. Liquid in
open vessels are slightly disturbed.
In
standing motor cars the shock is noticeable.

Single, few About 5 percent
About 50 percent

1.

is felt only by individual people at rest in
houses, especially on upper floors of
buildings.

qfQuantitv:

Many

Scale

IS 1893( Part 1 ) :2002
6.

roads on steep slopes; cracks in ground
upto widths of several centimetres. Water
in lakes become turbid. New reservoirs
come into existence. Dry wells refill and
existing wells become dry. In many cases,
change in flow and level of water is
observed.

Frightening

i)

ii)

Felt by most indoors and outdoors. Many
people in buildings are frightened and
run outdoors. A few persons loose their
balance. Domestic animals run out of
their stalls. In few instances, dishes and
glassware may break, and books fall down.
Heavy furniture may possibly move and
small steeple bells may ring.

9.

i)

Damage of Grade 1 is sustained in single
buildings of Type B and in many of Type
A. Damage in few buildings of Type A
is of Grade 2.

Darnuge qf’ h uildingv

i)

ii)

Most people are frightened and run
outdoors. Many find it difllcult to stand.
The vibration is noticed by persons
driving motor cars. Large bells ring.
In many buildings of Type C damage of
Grade 1 is caused: in many buildings of
Type B damage is of Grade 2. Most
buildings of Type A suffer damage of
Grade 3, few of Grade 4. In single
instances, landslides of roadway on steep
slopes: crack inroads; seams of pipelines
damaged; cracks in stone walls.

Destruction

i)

of buildings

General panic; considerable damage to
furniture. Animals run to and fro in
confusion, and cry.

iii) On flat land overflow of water, sand and
mud is often observed. Ground cracks
to widths of up to 10 cm, on slopes and
river banks more than 10 cm. Further
more, a large number of slight cracks in
ground; falls of rock, many land slides
and earth flows; large waves in water.
Dry wells renew their flow and existing
wells dry up.
10. General destruction

iii) Waves are formed on water, and is made
turbid by mud stirred up, Water levels
in wells change. and the flow of springs
changes. Some times dry springs have
their flow resorted and existing springs
stop flowing. In isolated instances parts
of sand and gravelly banks slip off.
8.

damage

ii) Many buildings of Type C stier damage
of Grade 3, and a few of Grade 4. Many
buildings of Type B show a damage of
Grade 4 and a few of Grade 5. Many
buildings of Type A suffer damage of
Grade 5. Monuments and columns fall.
Considerable damage to reservoirs;
underground pipes partly broken, In
individual cases, railway lines are bent
and roadway damaged.

iii) In few cases, cracks up to widths of
1cm possible in wet ground in mountains
occasional landslips: change in flow of
springs and in level of well water are
observed.
7.

General

i)

of buildings

Fright and panic; also persons driving
motor cars are disturbed, Here and there
branches of trees break off. Even heavy
furniture moves and partly overturns.
Hanging lamps are damaged in part.

of building~

Many buildings of Type C suffer damage
of Grade 4, and a few of Grade 5. Many
buildings of Type B show damage of
Grade 5. Most of Type A have
destruction of Grade 5. Critical damage
to dykes and dams. Severe damage to
bridges. Railway lines are bent slightly.
Underground pipes are bent or broken.
Road paving and asphalt show waves.

ii) In ground, cracks up to widths of several
cent.imetres,sometimesup to 1m, Parallel
to water courses occur broad fissures.
Loose ground slides from steep slopes.
From river banks and steep coasts,
considerable landslides are possible. In
coastal areas, displacement of sand and
mud: change of water level in wells; water
from canals, lakes. rivers. etc. thrown
on land. New lakes occur.

ii) Most buildings of Type C suffer damage
of Grade 2, and few of Grade 3, Most
buildings of Type B suffer damage of
Grade 3. Most buildings of Type A suffer
damage of Grade 4. Occasional breaking
seams.
Memorials and
of pipe
monuments move and twist. Tombstones
o~.erturn. Stone walls collapse.

11, Destruction
i)

iii) Small landslips in hollows and on banked
j4

Severe damage even to well built
buildings. bridges, water dams and

!
IS 1893( Part 1 ) :2002
railway lines. Highways become useless
Underground pipes destroyed.

ground are
destroyed.

12, Land.~cape changes
i)

damaged

or

ii) The surface of the ground is radically
changed. Considerable ground cracks
with extensive vertical and horizontal
movements are observed. Falling of rock
and slumping of river banks over wide
areas, lakes are dammed; waterfalls
appear and rivers are deflected. The
intensity of the earthquake requires to
be investigated specially.

ii) Ground considerably distorted by broad
cracks and fissures, as well as movement
in horizontal and vertical directions.
Numerous landslips and falls of rocks.
The intensity of the earthquake requires
to be investigated specifically,

&

greatly

Practically all structures above and below

ANNEX E
( Foreword)
ZONE FACTORS FOR SOME IMPORTANT TOWNS
Town

Zone

Zone Facto< Z

Tb wn

Zone

Zone Facto< Z

Chitradurga

II

0.10

Coimbatore

HI

0,16

Cuddalore

III

0.16

0.10

Cuttack

111

0.16

Iv

0,24

Darbhanga

v

0.36

Ambala

IV

0.24

Darjeeling

lv

0.24

Arnritsar

Iv

0.24

Dharwad

III

0.16

Asansol

III

0,16

Debra Dun

N

0.24

Aurangabad

H

0.10

Dharampuri

III

0,16

Bahraich

w

0,24

Delhi

Iv

0,24

Bangalore

II

0.10

Durfypur

111

0,16

Barauni

Iv

0.24

Gangtok

N

().24

Bareilly

III

0.16

Guwahati

v

0,36

Belgaum

III

0.16

Goa

111

0.16

Bhatinda

III

0.16

Gulbarga

II

0.10

Bhilai

I1

0.10

Gaya

III

0.16

Bhopal

D

0.10

Gorakhpur

N

0.24

Bhubaneswar

111

0.16

Hyderabad

II

0.10

Blmj

v

0.36

hllphd

v

0.36

Bijapur

III

0.16

Jabalpur

111

0.16

Bikaner

III

0.16

JaipLLr

II

0.10

Bokaro

Agra

III

0.16

Ahmedabad

HI

0.16

Ajmer

II

0,10

Allahabad

11

Ahnora

111

0.16

Jamshedpur

H

0,10

Bulandshahr

Iv

0,24

Jhansi

II

0.10

Burdwan

111

0.16

Jodhpur

II

0.10

Cailcut

HI

0.16

Jorhat

v

0,36

Chandigarh

N

().24

Kakrapara

111

().16

Chcnnai

111

0.16

Kalapakkam

111

0.16

35

IS 1893( Part 1 ) :2002
70wn

Zone

Zone Factor

Z

Town

Zone

Zone Factoc

Kanchipuram

III

0.16

Pondicherry

II

0.10

Kanpur

III

0.16

Pune

III

0.16

Karwar

III

0.16

Raipur

II

0.10

Kohima

v

0.36

Rajkot

III

0.16

Kolkata

III

0.16

Ranchi

II

0.10

Kota

II

0,10

Roorkee

W

0.24

II

0.10

Kurnool

II

0.10

Rourkela

Lucknow

III

0.16

Sadiya

v

0.36

Ludhiana

Iv

0.24

Salem

III

0.16

Madurai

II

0.10

Simla

lv

0.24

II

0.10

III

0.16

Snnagar

v

0.36

Surat

III

0.16

Tarapur

III

0.16

Tezpur

v

0.36

Mandi

v

0.36

Sironj

Mangalore

III

0.16

Solapur

Monghyr

w

0,24

Moradabad

IV

0,24

Mumbai

III

0.16

Mysore

It

0,10

Nagpur

II

0.10

Nagarjunasagar

II

0.10

Nainital

lv

0.24

Nasik

III

0.16

Nellore

III

0.16

Udaipur

Osmanabad

III

0.16

Panjim

III

0.16

Patiala

III

0.16

Patna

lv

0.24

Pilibhit

lv

0,24

36

Thane

III

0.16

Thanjavur

II

0.10

Thiruvananthapuram

III

0.16

Tiruchirappali

II

0.10

Tiruvennamalai

III

0.16

II

0.10

Vadodara

III

0.16

Varanasi

IiI

0.16

Vellore

III

0.16

Viayawada

IN

0.16

Vkhakhapatnam

It

0.10

Z

IS 1893( Part 1 ): 2002

ANNEX
(

F

Foreword)

COMMITTEE COMPOS~ON
Earthquake Engineering Sectional Committee, CED 39
Representative(s)

Organization

I

In personal capcity ( 72/6 Civil Lines, Roorkee 247667)

DR A. S. AR~A( Chairman )

Bharat Heavy Electricrd Ltd, New Delhi

SHRIN. C. ADDY
DR C. KAME.SHWARA
RAO ( Alternate 1 )
SHRIA. K. SINGH( Alternate 11 )

Building
Materials
New Delhi

Technology

SHRIT. N. GUPTA
SHRIJ. K. PRASAD( Alternate )

Council,

Central Building Research Institute, Roorkee

SHRIS. K. MHTAL
SHRIV. K. GUPTA( Alternate )

Central Public Works Department, New Delhi

SUPERINTENDING
ENGINEER(D)
EXECUTIVE
ENGINEER(D) HI ( Alternate )

Central Water Commission ( ERDD ), New Delhi

DIRECTOR
CMDD ( N&W )
DIRECTOR
EMBANKMENT
( N&W) ( Alternate)

Central Water and Power Research Station,

SHRI1. D. GUPTA
SHRI S. G. CHAPHALAKAR
( Alternate )

D-CAD Technologies

Department

Pune

DR K. G. BHATIA

Pvt Ltd, New Delhi

Delhi College of Engineering,

DR ( SHRIMATI
) P. R. BOSE

Delhi

SHRIP. C. KGTESWAR
RAO
SHRIS. RAMANLHAM
( Alternate )

of Atomic Energy, Mumbai

Department of Civil Engineering,
Roorkee
Department of Earthquake
Roorkee, Roorkee

Engineer-in-Cbief’s

&

Promotion

University

Engineering,

PROFASHOKJAIN

of Roorkee,

University

DR S.K. THAKKAR
DR D.K. PAUL( Alernate I )
DR S. BASU( Alrernate 11 )

of

COL ( DR

) SHRIPAL
SHRIY. K. SINGHAL( Alternate )

Branch, Army Headquarters, New Delhi

Engineers India Ltd, New Delhi

DR V. Y. SALPEKAR
SHRIR. K. GROVER( Alternate )

Gammon India Limited, Mumbai

SHRIS. A. REDDI
SHRIA. K. CHATTERJEE
( Alternate 1 )
SHRIV. N. HAGGADE( Alternate 11 )

Geological

SHRIP. PANDEY
SHRIY. F?SHARDA( Alternate )

Survey of India, Lucknow

t
Housing Urban and Development

Corporation,

SHRIV. ROY
SHRID. P. SINGH( Alternate )

New Delhi

Indian Institute of Technology, Kanpur

DR S. K. JAIN
DR C. V. R. MURTY( Alternate )

Indian Institute

DR RAW SINHA
DR A. GOYAL( Al?ernate )

of Technology, Mumbai

Indian Meteorological Department,

DR S. N. ,BHAITACHARYA
SHRIV. K. MITTAL( AJternate )

New Delhi

I

( Continued on page 38)
I

-

37

IS 1893( Part 1 ): 2002
( Continued from page 37)
Representative(s)

Organization
Indian Society of Earthquake Technology, Roorkee

SHRIM. K. GUPTA
DR D. K. PAUL( Alrernate )

Larsen and Toubro, Chennai

SHRIK. JAYARAMAN
SHRIS. KANAPPAN
( Alternate )

Maharashtra Engineering

SHRIR. L. DAMANI
SHRIS. V. KUMARASWAMY( Alternate )

Research Centre ( MERI ), Nasik

Ministry of Surface Transport, New Delhi

SHRIN. K. SINHA
SHRIR. S. NINAN( Alternate )

National Geophysical Research Institute ( CSIR ), Hyderabad

SHRIS. C. BHATIA
SHRIM. RAVIKUMAR( Alternate )

NationaJ Highway Authority of India, New Delhi

SHRIN. K. SINHA
SHRIG. SHARAN( Alternate )

National Hydro-Electric

CHIEPENGINEER,CD-HI

Power Corporation Ltd, New Delhi

National Thermal Power Corporation Ltd, New Delhi

SHRIR. S. BAJAI
SHRIH. K. RAMKUMAR
( Alternate )

North Eastern Council, Shillong

SHRIL. K. GANJU
SHRIA. D. KHARSHING
( Alternate )

Nuclear Power Corporation,

SHRtU. S. P. VERMA

Railway

Mumbai

Board, Ministry of Railways,

School of Planning and Architecture,
Structural Engineering

Tandon Consultants

EXECUTIVEDIRECTOR( B&S )
JOINTDIRECTOR( B&S ) CB-1 ( Alternate )

Lucknow

SHRIV. THIRUVENDGADAM

New Delhi

SHRI C. V. VAIDYANATErAN
DR B. SWARAMSARMA( Alternate )

Research Centre ( CSIR ), Chennai

DR MAHESHTANDON
SHRIVINAYGUPTA( Alternate )

Ltd, New Delhi

SHRI K. V. SUBRA~ANIAN
SHRIM. K. S. YOGI( Alternate

Tata Consulting Engineers, Mumbai

)

Wadia Institute of Himalayan Geology, Debra Dun

SHRISURINDERKUMAR

In personal capacity ( E-53, Kapil Whan Faridabad )

SHRIP. L. NARULA

BIS Directorate GeneraJ

SHRt S.K. JAIN, Director & Head ( Civ Engg )
[ Representing Director General ( Ex-officio ) ]
Member-Secretary
SHRIS. CHATURVEDI
Joint Director ( Civ Engg ), BIS

Earthquake Resistant Construction Subcommittee, CED 39:1
In personal capacity ( 72/6 Civil Lines, Roorkee 247667)

DR A. S. ARYA( Convener)

Building Material Technology Promotion Council, New Delhi

SHRIT. N. GUPTA
SHRIJ. K. PRASAD( Alternate )

Central Building Research Institute, Roorkee

SHRIM. P. JAISINGH
SHRIV. K. GUPTA( Alternate )

( Continued on page 39)

38

IS 1893( Part 1 ): 2002
( Continued from page 38)
Representative(s)

Organization
Central Public Works Department,

Delhi College of Engineering,
Department of Earthquake
Roorkee, Roorkee
Engineer-in-Chief’s

OFWORKS( NDZ )
SUPERINTENDING
ENGINEER(D) ( Alternate

New Delhi

SUPERINTENDING SURVEYOR

DR ( SHRIMATI
) P. R. BOSE

Delhi
Engineering,

University

Branch, Army Headquarters,

Housing and Urban Development

Corporation,

DR S. K. THAKKAR
DR D. K. PAUL( Alternate )

of

EXECUTIVE
ENGINEER( DESIGN)

New Delhi

SHRIB. K. CHAKRABORTY
SHRID. P. SINGH ( Alternate )

New Delhi

Hindustan Prefab Ltd, New Delhi

SHRIM. KUNDU

Indian Institute of Technology, Mumbai

DR ALOKGOYAL
DR RAVISINHA ( Al[ernate )

Indian Institute of Technology,

DR SUDHIRK. JAIN

Kanpur

DR C. V. R. MURTY (

Alternate )

North Eastern Council, Shillong

SHRi D. N. GHOSAI

Public Works Department,
Simla

Goverment of Himachat Pradesh,

SHRIV. KAPUR
SHRI V. K KAPOOR(

Public Works Department,

Goverment of Jammu & Kashmir

SHRI G. M. SHOUNTHU

Public Works Department,

Goverment of Assam, Guwahati

SHRI SUBRATACHAKRAVARTY

Alternate )

Public Works Department, Government of Gujarat, Gandhi Nagar

SUPERINTENDING
ENGINEER( DESIGN )

Research, Design and Standards Organization,

JOINTDIRECTORSTDS (B&S)lCB-I
ASSISTANTDIRECTORSTtX ( B&S )/CB-11
( Alternate)

Structural Engineering

)

Lucknow

Research Centre ( CSIR ), Chennai

SHRf C. V. VAIDYANATHAN
SHR1B. StVARAMASARMA (

Tandon Consultants Pvt Ltd, Delhi

DR MAHESH TANDON
SHRIVINAYGUPTA(

Alternate )

Alternate )

Maps Subcommittee, CED 39:4
In personal capacity ( E-53 Kapil VihaC Faridabad )

SHRI P. L. NARULA ( Convener )
BRIG K. K. GUPTA( Alternate

DIRECTOR
SHRIL D. GUPTA( Alternate)

Centrrd Water and Power Research Station, Pune

Department of Earthquake
Roorkee, Roorkee

Engineering,

Indian Meteorological Department,

University

DR S. BASU
DR ASHWANI
KUMAR( Alternate)

of

DR S. N. BHATTACHARYA
SHRI V. K. MHTAL ( Alternate )

New Delhi

Institute of Petroleum Engineering Oil and Natural Gas
Commission,

)

Debra Dun

DEPUTY GENERALMANAGER
SUPERINTENDING
GEOPHYSICIST(

National Geophysical Research Institute ( CSIR ), Hyderabad

SHRIS, C. BHATIA
DR B. K. RASTOG]( Alternate )

Survey of India, Debra Dun

SHRIG. M. LAL

39

Alternate )

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