This MCQ module is based on: Production Function & Marginal Product
TOPIC 6 OF 13
Production Function & Marginal Product
🎓 Class 12
Economics
CBSE
Theory
Chapter 3 — Production and Costs
⏱ ~25 min
🌐 Language: [gtranslate]
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The Production Function, TP/AP/MP & the Law of Variable Proportions
Why does a single farmer with 4 hectares of land produce more grain when the second worker arrives, but actually less per worker once the eighth helper is added? Why can a tailor sew shirts faster when one extra sewing machine is installed, but only up to a point? The answer lies in one of the most beautiful regularities of microeconomics — the relationship between inputs and output. This part of NCERT Chapter 3 sets up the producer's side of the market: the production function, the difference between short and long run, total/average/marginal product, and the law that quietly governs every factory floor — the Law of Variable Proportions.
3.0 Why Study the Producer?
Chapter 2 examined the consumer; this chapter examines the producer (the firm). Production is the process by which inputs are transformed into output. A tailor uses a sewing machine, cloth, thread and his own labour to produce shirts. A farmer uses land, labour, a tractor, seeds, fertiliser and water to produce wheat. A car-maker uses land for a factory, machinery, labour and various other inputs (steel, aluminium, rubber) to produce cars. A rickshaw puller uses a rickshaw and his own labour to produce rickshaw rides. A domestic helper uses her labour to produce cleaning services.
To keep the analysis simple, NCERT makes two assumptions:
Instantaneous Production
No time elapses between combining inputs and producing output. The firm is treated as if it can convert factors into output the moment they are hired.
Production = Supply
The terms production and supply are used synonymously. Whatever is produced is assumed to reach the market.
Cost of Production
To acquire inputs the firm must pay for them — this payment is the firm's cost of production.
Profit Maximisation
Revenue minus cost equals profit. The firm's objective is to earn the maximum profit it can — every rule that follows flows from this single objective.
3.1 The Production Function
The production function? of a firm describes the relationship between inputs used and output produced. For different quantities of inputs employed, it tells us the maximum quantity of output that can be produced.
Consider the farmer above. Suppose he uses only two inputs to produce wheat — land and labour. The production function tells us the maximum amount of wheat he can produce for any combination of these two. If, for instance, he uses 2 hours of labour per day on 1 hectare of land and gets a maximum of 2 tonnes of wheat, the rule that links 2 hours, 1 hectare and 2 tonnes is what we call his production function.
One simple algebraic example might be:
q = K × L
where q = wheat output, K = land in hectares, L = hours of labour per day
where q = wheat output, K = land in hectares, L = hours of labour per day
Such a description tells us the exact link between inputs and output. If either K or L rises, q rises. For any (L, K) combination there is exactly one q. Because by definition the production function reports the maximum output, it deals only with the efficient use of inputs — given the inputs, no further output can be squeezed out without changing technology.
📖 Production Function — NCERT
The production function gives the maximum quantity of output that can be produced by a firm using different combinations of factors of production, given the existing technology.
A production function is defined for a given technology. If technology improves, the maximum output obtainable for the same input combinations rises — and we have a new production function altogether.
Two-Factor Notation: Labour and Capital
Inputs used by a firm are called factors of production?. In principle a firm may employ many factors, but to keep the discussion tractable NCERT considers only two — labour (L) and capital (K). The production function then takes the standard form:
q = f(L, K) …(3.1)
Equivalently: q = f(x₁, x₂) where x₁ = labour, x₂ = capital
Equivalently: q = f(x₁, x₂) where x₁ = labour, x₂ = capital
Here L (or x₁) is the units of labour, K (or x₂) is the units of capital, and q is the maximum output that can be produced.
A Numerical Example — NCERT Table 3.1
Table 3.1 below presents a numerical production function. The left column shows units of labour; the top row shows units of capital. The cell at any row–column pair gives the maximum output for that (L, K) combination. As you move right along a row, capital rises; as you move down a column, labour rises.
| Labour ↓ | Capital → | ||||||
|---|---|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 | 6 | |
| 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
| 1 | 0 | 1 | 3 | 7 | 10 | 12 | 13 |
| 2 | 0 | 3 | 10 | 18 | 24 | 29 | 33 |
| 3 | 0 | 7 | 18 | 30 | 40 | 46 | 50 |
| 4 | 0 | 10 | 24 | 40 | 50 | 56 | 57 |
| 5 | 0 | 12 | 29 | 46 | 56 | 58 | 59 |
| 6 | 0 | 13 | 33 | 50 | 57 | 59 | 60 |
Read Table 3.1 carefully. With 1 unit of labour and 1 unit of capital, the firm can produce at most 1 unit of output. With 2 labour + 2 capital it can produce 10 units. With 3 labour + 2 capital it can produce 18 units. Both inputs are necessary — if either one is zero (the entire first row or first column), output is zero. With both inputs positive, output is positive. As either input rises, output rises.
🟣 Isoquant — Just an Indifference Curve in Disguise
From Chapter 2 you remember the indifference curve: every bundle on the curve gives the same satisfaction. The producer's analogue is the isoquant? — the set of all (L, K) combinations that yield the same level of output.
Look at Table 3.1. Output of 10 units can be produced by three combinations: (4L, 1K), (2L, 2K), (1L, 4K). All three lie on the isoquant labelled q = 10.
Place L on the X-axis and K on the Y-axis; isoquants for higher output levels lie further from the origin. Because more of one input means less of the other is needed for the same output (when both have positive marginal products), isoquants slope downward from left to right.
3.2 The Short Run and the Long Run
Before going further we must distinguish two time concepts that economists use repeatedly.
Short Run
At least one factor (labour or capital) cannot be varied — it is the fixed factor. Output can be changed only by changing the variable factor. Capital is typically the fixed factor; labour is the variable factor.
Long Run
All factors of production can be varied. There is no fixed factor. Both labour and capital can be adjusted simultaneously.
The long run is generally a longer time period than the short run, but the cut-off in calendar time differs across industries. A roadside chai stall can buy a new kettle in a day; a steel plant cannot install a new blast furnace in less than three years. So instead of pegging the short and long run to days, months or years, NCERT defines them by whether all inputs can be varied or not.
Use Table 3.1. In the short run, suppose capital is fixed at 4 units. Then the firm can vary only labour — and the column under K = 4 (output values 0, 10, 24, 40, 50, 56, 57) is the firm's short-run output schedule.
3.3 Total Product, Average Product, Marginal Product
3.3.1 Total Product (TP)
Vary one input and hold all others constant — the relationship between the variable input and the resulting output is called the total product? of that variable input. It is also called the total return to, or the total physical product of, the variable input.
From Table 3.1, fix capital at K = 4 and read down: as labour rises 0 → 1 → 2 → 3 → 4 → 5 → 6, total product is 0 → 10 → 24 → 40 → 50 → 56 → 57. This is the total product of labour schedule (with K = 4) and is shown again in the second column of Table 3.2 below.
3.3.2 Average Product (AP)
Average product? is the output per unit of the variable input. With labour as the variable input:
APL = TPL ÷ L …(3.2)
3.3.3 Marginal Product (MP)
Marginal product? of an input is the change in output per unit change in the input, when all other inputs are held constant. With capital fixed:
MPL = ΔTPL ÷ ΔL …(3.3)
Equivalently: MPL = (TP at L units) − (TP at L − 1 unit) …(3.4)
Equivalently: MPL = (TP at L units) − (TP at L − 1 unit) …(3.4)
Where Δ ("delta") simply means "change in". Since inputs cannot be negative, marginal product is undefined at zero input. For any level of an input, the sum of marginal products of every preceding unit gives the total product. Total product is the sum of marginal products.
A Worked Example — NCERT Table 3.2
Using Table 3.1 with K = 4, we now compute AP and MP at each level of labour.
| Labour (L) | Total Product (TP) | Marginal Product (MPL) | Average Product (APL) |
|---|---|---|---|
| 0 | 0 | — | — |
| 1 | 10 | 10 | 10.00 |
| 2 | 24 | 14 | 12.00 |
| 3 | 40 | 16 | 13.33 |
| 4 | 50 | 10 | 12.50 |
| 5 | 56 | 6 | 11.20 |
| 6 | 57 | 1 | 9.50 |
How the columns are computed. Column 3 (MP) divides the change in TP by the change in L. For example, when L goes from 1 to 2, TP changes from 10 to 24. ΔTP = 14, ΔL = 1, so MP of the 2nd worker = 14 ÷ 1 = 14. Column 4 (AP) divides TP by L. When L = 3, AP = 40 ÷ 3 = 13.33.
⭐ NCERT Identity — TP = sum of MPs
For any level of input employment, total product equals the sum of all marginal products up to that level. Verify with Table 3.2: at L = 4, MP₁ + MP₂ + MP₃ + MP₄ = 10 + 14 + 16 + 10 = 50 = TP at L = 4. ✔
Figure 3.A — TP, AP and MP of labour from Table 3.2 (capital fixed at K = 4). TP rises throughout (then almost flattens). MP first rises (1 → 14 → 16) then falls (16 → 10 → 6 → 1). AP also first rises and then falls — and MP cuts AP at AP's maximum.
3.4 The Law of Diminishing Marginal Product / Law of Variable Proportions
Plot the data of Table 3.2 — labour on the X-axis, output on the Y-axis. Notice the shape of TP: it rises throughout, but the rate at which it rises is not constant. When labour goes from 1 to 2, TP rises by 14. From 2 to 3 it rises by 16. From 3 to 4 it rises by only 10. The rate of increase is the marginal product. MP first rises (from 10 to 14 to 16), then falls (16 to 10 to 6 to 1).
📖 Law of Variable Proportions / Law of Diminishing Marginal Product — NCERT
The marginal product of a factor input initially rises with its level of employment. After a certain level of employment, however, it starts to fall. This tendency is called the law of variable proportions or the law of diminishing marginal product.
Why Does MP First Rise, Then Fall?
To make sense of this, NCERT introduces the idea of factor proportions — the ratio in which the two inputs are combined. Hold one factor fixed and keep increasing the other. Initially, the factor proportions become "more suitable" for production: each extra unit of the variable input pairs better with the fixed factor, and MP rises. But after a certain level the production process becomes too crowded with the variable input. The fixed factor (say, land) is stretched too thin per unit of the variable input — and MP starts to fall.
NCERT's farmer story is the cleanest illustration. Suppose Table 3.2 describes a farmer with 4 hectares of land who chooses how much labour to apply.
L = 1
One worker, 4 hectares
Far too much land for one worker to cultivate. Labour is severely under-utilised. MP just 10.
L = 2 → 3
Each new worker pairs better
Labour-to-land ratio improves; specialisation begins. MP rises to 14, then to 16. Factor proportions are getting "right".
L = 4
Land starts getting crowded
Each worker has insufficient land to operate efficiently. MP falls to 10. The Law of Diminishing Marginal Product has taken hold.
L = 5 → 6
Workers in each other's way
MP drops to 6, then 1. Adding more labour to the same 4 hectares contributes very little extra wheat.
The Three Stages of Production
The behaviour of the variable input traditionally divides production into three stages. Although NCERT names only the underlying law, every CBSE answer should distinguish the three stages because they explain where a rational producer should operate.
Figure 3.B — Three stages of production. Stage I: increasing returns (MP rising, AP rising). Stage II: diminishing returns (MP falling, AP falling, both still positive — TP still rising). Stage III: negative returns (MP < 0, TP falls). A rational producer always operates in Stage II.
| Stage | Marginal Product (MP) | Average Product (AP) | Total Product (TP) | Returns |
|---|---|---|---|---|
| Stage I | Rising, MP > AP | Rising | Rising at increasing rate | Increasing returns to factor |
| Stage II | Falling, MP < AP, MP still ≥ 0 | Falling | Rising at decreasing rate up to TP-max | Diminishing returns to factor |
| Stage III | MP < 0 | Falling | Falling | Negative returns to factor |
🎯 Where Does the Rational Producer Operate?
A rational producer never operates in Stage I (because output is still rising even faster than employment — adding more variable input is always profitable so far) and never in Stage III (because MP is negative — adding more input reduces output). She operates in Stage II, where MP and AP are positive but falling, and where the actual profit-maximising output is determined by the cost and price equation studied in Chapter 4.
LET'S EXPLORE — Verify the TP = ΣMP Identity
- Take Table 3.2 with K fixed at 4. Write out the MP column: —, 10, 14, 16, 10, 6, 1.
- For L = 1, 2, 3, 4, 5, 6, compute the running sum of MP entries.
- Compare each running sum with the TP value at the same L. They must match exactly.
- What does this identity tell you about the area under the MP curve?
- From the same table, identify the value of L at which MP starts falling. What economic event does this mark?
Sample finding. Running sums of MP: at L = 1 → 10; at L = 2 → 10 + 14 = 24; at L = 3 → 24 + 16 = 40; at L = 4 → 40 + 10 = 50; at L = 5 → 50 + 6 = 56; at L = 6 → 56 + 1 = 57. Each running sum exactly equals the corresponding TP value in Table 3.2. The identity tells us that the area under the MP curve from 0 to L equals TP at L — a graphical version of the same statement. MP starts falling at L = 4 (16 → 10) — this is the point where Stage I ends and Stage II (diminishing returns) begins.
THINK ABOUT IT — Production in Your Kitchen
- Imagine your family kitchen with one stove (capital fixed at 1) and a varying number of cooks (variable input).
- Estimate how many chapatis can be produced in 30 minutes with 1, 2, 3, 4 and 5 cooks at the same stove.
- Compute MP and AP. At which cook does MP first start to fall? Explain why.
- Could you ever reach a stage where MP becomes negative? What would have to happen?
Sample finding. A reasonable schedule: 1 cook → 12 chapatis; 2 cooks → 28 (MP = 16, division of labour); 3 cooks → 38 (MP = 10, the stove is the bottleneck); 4 cooks → 42 (MP = 4, kitchen crowded); 5 cooks → 40 (MP = −2, cooks bumping into each other). MP falls after the 2nd cook because the fixed stove starts limiting output. MP turns negative at the 5th cook because additional bodies physically obstruct work — Stage III.
📝 Competency-Based Questions — Apply, Analyse, Evaluate, Create
Scenario. A small textile firm has 4 looms (capital fixed) and hires weavers (the variable input). Its TP schedule is: L = 1 → 8 metres; L = 2 → 20; L = 3 → 36; L = 4 → 48; L = 5 → 56; L = 6 → 60; L = 7 → 60; L = 8 → 56.
Q1. Compute the AP and MP schedules for this firm and identify the labour-employment level at which Stage II of production begins.
L3 Apply
Answer. MP = 8, 12, 16, 12, 8, 4, 0, −4. AP = 8, 10, 12, 12, 11.2, 10, 8.57, 7. MP rises from L = 1 to L = 3 (8 → 12 → 16) and falls from L = 4 onwards. Stage II therefore begins at L = 4 (where MP first falls but is still positive). Stage III begins at L = 8 (MP becomes negative).
Q2. The firm is currently employing 7 weavers. A consultant suggests reducing the workforce. Use the data to evaluate whether the consultant is right.
L4 Analyse
Answer. At L = 7, MP = 0 — the seventh weaver adds no extra output. At L = 8, MP = −4 — adding the eighth weaver actually reduces total output. The firm is on the boundary of Stage III. Reducing the workforce to L = 6 (where TP is also 60 but with one fewer worker on the wage bill) leaves output unchanged while saving labour cost. The consultant is correct: the firm is at the edge of negative returns and should not retain workers whose marginal product is zero or negative.
Q3. Suppose the firm leases two more looms (capital rises from 4 to 6). Predict, without recomputing the table, what will happen to the entire MP-of-labour curve and explain why.
L5 Evaluate
Answer. Adding two looms raises the capital input but leaves the production function unchanged. With more capital paired with each weaver, the factor proportions improve at every L. The MP-of-labour curve therefore shifts upward at all employment levels. The point at which MP starts to fall (the boundary between Stage I and Stage II) moves to a higher L because the looms are no longer a tight bottleneck. Output increases for every L, and the firm can profitably employ more weavers than before.
Q4. The firm is told that "if doubling labour doubles output, the firm has constant returns to scale". The owner uses Table 3.2 (in the chapter) to argue that doubling L from 2 to 4 raises TP from 24 to 50, which is more than double — therefore the firm has IRS. Diagnose the error.
L4 Analyse
Answer. Returns to scale is a long-run concept that requires all inputs to be doubled (or scaled up). Here the owner has doubled only labour while keeping capital fixed at 4. That is the short-run Law of Variable Proportions, not the long-run Returns to Scale. The owner has confused two different concepts. To check returns to scale he must double both L and K (e.g. compare q at L = 2, K = 2 with q at L = 4, K = 4) and then compare the ratio.
HOT Q5. Design a one-paragraph argument that the Indian agricultural sector, dominated by small landholdings with rising rural population, suffers from "diminishing marginal product of labour" and that the long-run remedy must involve more land or capital, not more labour.
L6 Create
Answer. Indian agriculture, with land per worker among the lowest in the world and labour pressing in from rural population growth, is operating at very high L on a fixed K (land + irrigation infrastructure). The Law of Variable Proportions implies the MP of an extra agricultural worker is small and may even be near zero — a phenomenon empirically labelled "disguised unemployment" by Indian planners. Adding more labour to the same land cannot lift output meaningfully. The remedy must change the fixed factor: more irrigation, mechanisation, modern inputs (which is a capital expansion) and consolidation of holdings (which is a land-quality improvement). Equivalently, moving labour out of agriculture into manufacturing/services where its MP is higher. The policy implication of the Law of Variable Proportions is therefore deeply structural — not a short-run wage adjustment but a long-run reallocation of factors.
🎯 Assertion–Reason Questions
Assertion (A): The marginal product of a variable input first rises, reaches a maximum, and then falls.
Reason (R): As more of the variable input is used with a fixed factor, the factor proportions first become more suitable for production but eventually the production process becomes too crowded with the variable input.
Reason (R): As more of the variable input is used with a fixed factor, the factor proportions first become more suitable for production but eventually the production process becomes too crowded with the variable input.
Options: (a) Both A and R are true and R is the correct explanation of A. (b) Both A and R are true but R is not the correct explanation of A. (c) A is true, R is false. (d) A is false, R is true.
Correct answer: (a) — Both statements are NCERT-correct. R is precisely the mechanism by which A holds: the changing factor proportions first improve, then deteriorate, exactly producing the inverse U-shape of the MP curve.
Assertion (A): Total product is the sum of marginal products of all preceding units of the variable input.
Reason (R): Marginal product is defined as the change in total product per unit change in the variable input.
Reason (R): Marginal product is defined as the change in total product per unit change in the variable input.
Options: (a) Both A and R are true and R is the correct explanation of A. (b) Both A and R are true but R is not the correct explanation of A. (c) A is true, R is false. (d) A is false, R is true.
Correct answer: (a) — A is the NCERT identity TP = ΣMP. R defines MP as ΔTP/ΔL. Because each MP is a step-change in TP, the cumulative sum of these step-changes from 0 to L equals TP at L. R is exactly why A is true.
Assertion (A): In the short run, at least one factor of production cannot be varied.
Reason (R): The short run and the long run are defined by calendar time — short run is one year, long run is more than five years.
Reason (R): The short run and the long run are defined by calendar time — short run is one year, long run is more than five years.
Options: (a) Both A and R are true and R is the correct explanation of A. (b) Both A and R are true but R is not the correct explanation of A. (c) A is true, R is false. (d) A is false, R is true.
Correct answer: (c) — A is the NCERT definition of the short run and is correct. R is incorrect: NCERT explicitly says the short and long run are not defined in terms of days, months or years; they are defined by whether all inputs can be varied. Calendar time differs across industries.
📌 Quick Recap of Part 1
- Production function q = f(L, K) gives the maximum output for any (L, K) combination. It is defined for a given technology — a better technology means a new production function.
- Isoquant: set of (L, K) bundles yielding the same output. Just like indifference curves, but for production. Slopes downward when both factors have positive MP.
- Short run: at least one input is fixed (typically K). Long run: all inputs can be varied. Definition is by varability, not by calendar time.
- Total Product (TP) = relationship between variable input and output, holding others fixed.
- Average Product APL = TPL / L. Marginal Product MPL = ΔTPL / ΔL = TPL − TPL−1.
- Identity: TP = sum of all MPs up to that level (verified from Table 3.2: 10 + 14 + 16 + 10 = 50 = TP at L = 4).
- Law of Variable Proportions / Law of Diminishing Marginal Product: MP first rises, then falls — explained by changing factor proportions and crowding of the fixed factor.
- Three stages: Stage I (increasing returns, MP rising), Stage II (diminishing returns, MP falling but positive), Stage III (negative returns, MP < 0). Rational producer operates in Stage II.
Production Function
q = f(L, K): maximum output from any combination of inputs given technology.
Factors of Production
The inputs (labour, capital, land, etc.) used to produce output.
Isoquant
Set of (L, K) combinations yielding the same level of output.
Short Run
Time period in which at least one factor is fixed.
Long Run
Time period in which all factors are variable.
Total Product (TP)
Output produced by varying one input while all others are held constant.
Average Product (AP)
Output per unit of the variable input: APL = TPL / L.
Marginal Product (MP)
Change in output per unit change in the variable input: MPL = ΔTPL / ΔL.
Law of Variable Proportions
MP of a variable input first rises, then falls as employment increases (other factors fixed).
Stage II of Production
Region where MP is falling but still positive — the only stage in which a rational producer operates.
Frequently Asked Questions — The Production Function, TP/AP/MP & the Law of Variable Proportions
What is a production function in Class 12 Microeconomics?
A production function is the technical relation between the maximum output a firm can produce and the inputs used. In NCERT Class 12, the standard form is q = f(L, K), where q is output, L is labour and K is capital. The function captures the firm's technology — for any combination of labour and capital it gives the largest output that can be obtained with that bundle.
What is the difference between the short run and the long run?
In the short run at least one input is fixed — typically capital, such as the size of the factory — while other inputs like labour can be varied. In the long run all inputs are variable — the firm can adjust its plant, machines and workforce. NCERT Class 12 uses this distinction to study the law of diminishing marginal product (short run) and returns to scale (long run).
What are total product, average product and marginal product?
Total product (TP) is the total output produced when a given quantity of variable input is employed with a fixed input. Average product (AP) is output per unit of variable input, AP = TP / L. Marginal product (MP) is the addition to total output from one more unit of variable input, MP = ΔTP / ΔL. NCERT Class 12 derives all three from a typical TP schedule.
What is the relation between average product and marginal product?
When marginal product is greater than average product, average product rises. When marginal product equals average product, average product is at its maximum. When marginal product is less than average product, average product falls. Geometrically the MP curve cuts the AP curve from above at the maximum point of AP. NCERT Class 12 illustrates this with an arithmetic example.
What is the law of diminishing marginal product?
The law of diminishing marginal product states that as more units of a variable input are added to a fixed input, the marginal product first rises, reaches a maximum and then falls — eventually becoming zero or negative. The cause is that the fixed input becomes increasingly crowded relative to the variable input. NCERT Class 12 also calls this the law of variable proportions.
Why is the law of variable proportions a short-run phenomenon?
The law of variable proportions operates in the short run because at least one input is fixed — typically capital. Adding more workers to a fixed factory means each successive worker has less capital to work with, so marginal product eventually falls. In the long run all inputs are variable and the law no longer applies; instead the long-run analogue is returns to scale.
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