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Vertical Distribution of Base Shear — IS 1893:2016
IS 1893:2016 — Seismic Design PART 1
🔍
IS 1893 (Part 1) : 2016 · Clause 7.7

Vertical Distribution of
Seismic Base Shear

Learn exactly how earthquake forces are distributed floor-by-floor using the Qi formula — with interactive calculator, worked examples, and visual aids.

📐 Clause 7.7.7 📏 Equivalent Static Method 🏗️ Multi-Storey Buildings 🧮 Interactive Calculator
HomeIS 1893 Learning Hub › Vertical Distribution of Base Shear

📋 Contents

  1. The Big Picture — What is Base Shear?
  2. Why Distribute Forces Vertically?
  3. The Qi Formula — IS 1893 Clause 7.7.7
  4. Variable Dictionary
  5. Step-by-Step Calculation Procedure
  6. Worked Example
  7. Building Visualization
  8. Special Cases & Codal Notes
  9. 🧮 Interactive Calculator
  10. Key Takeaways & FAQs
1

The Big Picture — What is Base Shear?

🌍 Seismic Ground Motion

During an earthquake, the ground moves. Because of inertia, a structure tends to stay put while its base is dragged. This creates a horizontal inertia force at every mass point of the building.

🏗️ Total Base Shear (VB)

IS 1893 allows us to lump all seismic forces into a single horizontal resultant at the base called Base Shear (VB). This is computed using the Equivalent Static Analysis method.

📤 The Distribution Problem

Once VB is known, it must be shared among all floors. Each floor gets a portion Qi. The sum of all Qi must equal VB.

Base Shear — IS 1893 Clause 7.6.1 VB = Ah × W where Ah = Design horizontal seismic coefficient, W = Seismic weight of the building
2

Why Distribute Forces Vertically?

In a real earthquake, every floor with mass experiences an inertia force. Lower floors carry more total weight above them, but upper floors move MORE (higher acceleration in the first mode shape). IS 1893 reflects this with a parabolic distribution:

  • Floors with higher height AND higher weight attract more lateral force.
  • The distribution is not uniform — it follows a triangular-to-parabolic pattern.
  • This represents the first mode response of the building — the dominant mode in most regular buildings.
💡

Physical Intuition

Think of a flagpole in the wind. The base resists ALL the wind force (= VB), but the force is felt most at the top. A building behaves similarly under ground shaking — upper floors whip back and forth, experiencing higher acceleration than lower floors.

3

The Qi Formula — IS 1893 Clause 7.7.7

IS 1893 (Part 1): 2016, Clause 7.7.7 gives the lateral force at floor i as:

Clause 7.7.7 — Lateral Force at Floor i Qᵢ = Vᴮ × (Wᵢ · hᵢ²) / Σ(Wⱼ · hⱼ²) Summation Σ runs from j = 1 to n (ground floor level 1 to roof level n)
✔ Check: The sum of all floor forces must equal the total base shear: ΣQᵢ = Vᴮ
⚠️ Note on Ground Floor: For most buildings, h is measured from the base (plinth / ground level). The ground floor (i=1) often has h₁ = 0 or very small height, so Q₁ ≈ 0.
❓ Why is height squared (hᵢ²) in the formula?

The h² term comes from the assumption that the building vibrates in its first (fundamental) mode, and the first mode shape approximation is a straight-line (linear) displaced shape.


The inertia force at floor i is proportional to: mass × acceleration. The modal acceleration in the first mode is proportional to the mode shape ordinate, which is proportional to height (φᵢ ∝ hᵢ).


Modal participation × mode shape ordinate × mass gives: Wᵢ × hᵢ in numerator. When normalized by total Σ Wⱼhⱼ and the mode shape normalisation introduces another hᵢ, the combined effect becomes Wᵢhᵢ².


Summary: The h² weighting ensures that higher floors attract proportionally more force, mimicking the parabolic increase in acceleration typical of a first-mode vibrating structure.
❓ What is the role of Wi in the formula?

Wᵢ is the seismic weight of floor i. By Newton’s Second Law, Force = Mass × Acceleration. A heavier floor (higher Wᵢ) attracts more seismic force. The formula correctly weights each floor by both its mass and its height, so a heavy floor at a great height gets the maximum share of base shear.


Seismic weight = Dead Load of floor + Appropriate fraction of Live Load (as per Clause 7.3.1 of IS 1893:2016).

4

Variable Dictionary

Qᵢ Design lateral force at floor i (kN). This is what structural elements at that level must be designed to resist.
Vᴮ Total seismic base shear of the building (kN). Computed per Clause 7.6.
Wᵢ Seismic weight of floor i (kN). = DL + λ·LL per Clause 7.3.
hᵢ Height of floor i measured from the base of the structure (m).
n Total number of floors (including roof level). Ground = 1, Roof = n.
Σ Summation over all floors j = 1 to n. The denominator sums Wⱼhⱼ² for every floor.
Aₕ Design horizontal seismic coefficient = (Z/2)·(I/R)·(Sₐ/g). Per Clause 6.4.2.
W Total seismic weight of building = ΣWᵢ for all floors (kN).
Live Load Reduction (Clause 7.3.2): λ = 0.25 for LL ≤ 3 kN/m² and λ = 0.50 for LL > 3 kN/m². Roof live load is generally NOT counted in seismic weight.
5

Step-by-Step Calculation Procedure

Determine Seismic Zone & Parameters

Identify Zone (II–V), Importance Factor I, Response Reduction Factor R, and Soil Type. These set up Ah.

Compute Seismic Weight of Each Floor (Wᵢ)

Wi = Dead Load of slab + beams + columns (tributary to floor i) + λ × Live Load. Include floor finishes and partitions in DL.

Measure Heights (hᵢ) from Base

hi is the height of the floor level above the base (foundation level or plinth level). Ground floor slab may be at h = 0 m or the first level above ground.

Calculate Wi·hi² for Each Floor

Create a table: for each floor, multiply its seismic weight by the square of its height. Sum all these values to get the denominator Σ(Wj·hj²).

Compute Total Base Shear (Vᴮ)

VB = Ah × W where W = ΣWi. Use the fundamental natural period T to get Sa/g from Fig. 2 of IS 1893.

Apply the Qi Formula

For each floor: Qi = VB × [Wi·hi²] / [Σ(Wj·hj²)]. Verify that ΣQi = VB.

Apply Forces & Design

Qi is applied as a horizontal point load at each floor level. Use these forces to design structural members (beams, columns, shear walls) for the combined seismic load case.

6

Worked Example — 5-Storey Building

Problem: A 5-storey RC framed building has equal storey heights of 3.2 m. Seismic weight of each floor is as below. Total Base Shear VB = 650 kN. Find Qi at each floor.

Floor (i) Wᵢ (kN) hᵢ (m) hᵢ² (m²) Wᵢ·hᵢ² (kN·m²) Ratio (Wᵢhᵢ²/Σ) Qᵢ (kN)
Verification: Sum of all Qᵢ = VB = 650 kN ✔
7

Building Force Visualization

Schematic showing how lateral forces increase with height. Arrow length is proportional to Qi.

8

Special Cases & Codal Notes

⚠️ Ground Floor (h = 0)

If height of ground slab is taken as zero, then Q₁ = 0. This is physically correct — there is no relative inertia at ground level since the base moves with the ground. All seismic force is distributed to floors ABOVE ground.

🔄 Basement Floors

For buildings with basement, the height hi for basement levels can be taken as negative or zero depending on the assumption about the fixity point. IS 1893 typically considers the base at grade level.

🏠 Irregular Buildings

For plan/vertical irregularities, Dynamic Analysis (Response Spectrum Method) is mandatory (Clause 7.8). The Qi distribution is still used but derived from modal forces rather than the static formula.

🔝 Roof vs Top Floor

The topmost mass (roof) usually attracts the maximum Qi due to maximum hn and significant Wn. Always include water tanks, equipment, and parapet loads in Wn.

📌 Seismic Weight Composition (Clause 7.3.1 & 7.3.2)

Seismic weight of each floor = Full Dead Load + Appropriate fraction of Live Load


Imposed Load (Live Load)Fraction to Include (λ)
LL ≤ 3.0 kN/m²25% (λ = 0.25)
LL > 3.0 kN/m²50% (λ = 0.50)
Roof (accessible)No LL included
Storage loads100%
📌 Applicability of Equivalent Static Method (Clause 7.5.3)

The Equivalent Static Analysis (and hence the Qᵢ formula) is applicable only when:

  • Building height ≤ 15 m in Zones IV and V
  • Building height ≤ 15 m in Zones II and III with plan irregularities
  • Regular buildings up to 40 m height in Zones II and III
For taller or irregular buildings, Response Spectrum Method (RSM) must be used. The Qᵢ formula still applies but is applied mode-by-mode.
📌 Relationship with Storey Shear (Vᵢ)

The storey shear at any level i (the total shear force in the storey below floor i) is:

Storey Shear at Level i Vᵢ = Σ Qⱼ (sum from j=i to n) = sum of all lateral forces at or above floor i

This is used to design columns, shear walls, and connections in each storey.

🧮 Interactive Base Shear Distribution Calculator

IS 1893 (Part 1): 2016 — Clause 7.7.7 | Enter floor data and compute lateral force distribution

Floor Label Wi (kN) hi (m from base)
9

Key Takeaways & Common Mistakes

✅ Remember

  • ΣQᵢ MUST equal Vᴮ
  • Height is measured from the BASE, not floor-to-floor
  • Ground floor at h = 0 gets zero lateral force
  • Higher floors attract MORE lateral force (h² effect)
  • Seismic weight ≠ Gravity load

❌ Common Mistakes

  • Using storey height instead of cumulative height
  • Including full live load (use λ-fraction only)
  • Including roof live load in seismic weight
  • Forgetting to include self-weight of columns & beams
  • Not verifying ΣQᵢ = Vᴮ at the end
🎯

Core Formula to Remember

Qi = VB × (Wi·hi²) / Σ(Wj·hj²) — IS 1893:2016, Clause 7.7.7

Reference: IS 1893 (Part 1): 2016 — Criteria for Earthquake Resistant Design of Structures. Bureau of Indian Standards, New Delhi. | Educational resource for academic use.

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