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Introduction to Production and Resource Use Chapter 6
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Topics of Discussion Conditions of perfect competition Classification of productive inputs Important production relationships (Assume one variable input in this chapter) Assessing short run business costs Economics of short run production decisions 2
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Conditions for Perfect Competition Homogeneous products i.e., Corn grain, mined low-sulfur coal No barriers to entry or exit i.e., Regulatory, extremely high fixed costs Large number of sellers How large is large? Perfect information Information cost is relatively small No one firm has access to information and others don’t Page 86 3
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Classification of Inputs Economists view the production process as one where a variety of inputs are combined to produce a single or multiple outputs Cheese plant example Labor, cheese vats, milk, energy, starter cultures, cutting and wrapping tables, water, etc. Cheese, dry whey, whey protein concentrates are produced by the plant Pages 86-87 4
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Classification of Inputs Land: includes renewable (forests) and non-renewable (minerals) resources Labor: all owner and hired labor services, excluding management Capital: Manufactured goods such as fuel, chemicals, tractors and buildings that may have an extended lifetime Management: Makes production decisions designed to achieve specific economic goal Pages 86-87 5
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Classification of Inputs Inputs can also be classified depending on whether amount of input used changes with production level Fixed inputs: The amount used does not change with output level Up to a point the size of milking parlor does not change with ↑ milk production/cow or for initial ↑ in herd size Variable Inputs: The amount of input used changes with the level of output Usually the amount of labor supplied is a variable input (i.e., car assembly plant that ↑ the speed of assembly line to ↑ production/hour Pages 86-87 6
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Production Function Output = f(labor | capital, land, and management) Page 88 Start with one variable input Start with one variable input f() is general functional notation Could be any functional form Assume remaining inputs fixed at current levels Assume remaining inputs fixed at current levels 7
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Page 89 PointLabor (hr)Output A101.0 B163.0 C204.8 D226.5 E268.1 F329.6 G4010.8 H5011.6 I6212.0 J7611.7 Production Function We can graph the relationship between output and amount of labor used Known as the Total Physical Product (TPP) curve Purely a physical relationship, no economics involved X lbs of fertilizer/A generates a yield of Y 8
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Page 89 Total Physical Product (TPP) Curve Variable input Maximum Output ↓ Output 9
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Other Physical Relationships The following derivations of the TPP curve play an important role in decision-making Marginal Physical Product (MPP) = Average Physical Product (APP) = Page 90 10
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MPP = Change in output as you change input use Page 89 Production Function Point Labor [1] Output [2] ∆Labor [3] ∆Output [4] MPP [5] = [4] ÷ [3] A101.0----- B163.0620.33 C204.841.80.45 D226.521.70.85 E268.141.60.40 F329.661.50.25 G4010.881.20.15 H5011.6100.80.08 I6212.0120.40.02 J7611.7140.3-0.02 11
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Page 89 Total Physical Product (TPP) Curve Input MPP = 1.8/4.0 =.45 Output ↑ from 3.0 to 4.8 units = 1.8 Labor ↑ from 16 to 20 units = 4.0 Output 12
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Law of Diminishing Marginal Returns Pertains to what happens to the MPP with increased use of a single variable input If there are other inputs their level of use is not changed Diminishing Marginal Returns The MPP ↑ with initial use of a variable input At some point, MPP reaches a maximum with greater input use Eventually MPP ↓ as input use continues to ↑ Page 93 13
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Page 89 Point Labor [1] Output [2] ∆Labor [3] ∆Output [4] MPP [5] = [4] ÷ [3] A101.0----- B163.0620.33 C204.841.80.45 D226.521.70.85 E268.141.60.40 F329.661.50.25 G4010.881.20.15 H5011.6100.80.08 I6212.0120.40.02 J7611.7140.3-0.02 Production Function 14
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Plotting the MPP Curve Page 91 Change in output associated with a change in inputs Change from A to B on the production function → a MPP of 0.33 15
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Page 89 Point Labor [1] Output [2] ∆Labor [3] ∆Output [4] APP [6] = [2] ÷ [1] A101.0----- 0.10 B163.0620.19 C204.841.80.24 D226.521.70.30 E268.141.60.31 F329.661.50.30 G4010.881.20.27 H5011.6100.80.23 I6212.0120.40.19 J7611.7140.30.15 Production Function Average Physical Product (APP) = Amount of output/ amount of inputs used = Output/unit of input used Average Physical Product (APP) = Amount of output/ amount of inputs used = Output/unit of input used 16
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Page 89 Total Physical Product (TPP) Curve APP =.31 (= 8÷26) with labor use = 26 Output Input 17
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Page 91 Plotting the APP Curve APP = output level divided by level of input use Output divided by labor use at B (3 ÷ 16) =0.19 18
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Page 91 Definition of the Three Stages of Production APP is increasing in Stage I Stage I: MPP > APP APP is ↑ 19
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Page 91 Definition of the Three Stages of Production Stage II: MPP < APP MPP > 0 20
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Page 91 Definition of the Three Stages of Production Stage III: MPP < 0 21
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Page 91 Why are Stage I and Stage III irrational from the producer’s perspective? Definition of the Three Stages of Production 22
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Productivity is increasing as more inputs are being used so why stop if the average return is greater than cost? Can increase output by using less inputs: →More output and less cost Definition of the Three Stages of Production 23
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The question for the producer is: What level of input amount represented by Stage II should the I use? The question for the producer is: What level of input amount represented by Stage II should the I use? Definition of the Three Stages of Production 24
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Economic Dimension To answer the above question We need to account for the price of the product being produced We also need to account for the cost of the inputs used to produce the above product 25
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Key Cost Relationships The following cost concepts play key roles in determining where in Stage II a producer will want to produce Marginal Cost (MC) = total cost of production ÷ output produced as output level changes = variable cost of production ÷ output produced given that total fixed costs by definition do not change with output Average Variable Cost (AVC) = total variable cost of production ÷ total amount of output produced Page 94-96 26
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Key Cost Relationships The following cost concepts play key roles in determining where in Stage II a producer will want to produce Average Fixed Cost (AFC) = total fixed cost of production ÷ total amount of output produced Average Total Cost (ATC) = total cost of production ÷ total amount of output produced = AVC + ATC Page 94-96 27
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From TPP curve on page 113 From TPP curve on page 113 Page 94 28
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Fixed costs are $100 no matter the level of production Fixed costs are $100 no matter the level of production Page 94 29
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Total fixed costs (Col. 2) ÷ by total output (Col. 1) Total fixed costs (Col. 2) ÷ by total output (Col. 1) Page 94 30
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Page 94 Costs that vary with level of production Costs that vary with level of production 31
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Page 94 Total variable cost (Col. 4) ÷ by total output (Col. 1) 32
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Page 94 Total Fixed Cost (Col. 2) + Total Variable Cost (Col.4) 33
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Page 94 Change in Total Cost (Col. 4 or 6) associated with a change in output (Col. 1) 34
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Page 94 [Total Cost (Col. 6) ÷ by Total Output (Col. (1)] or [Avg. Variable Cost + Avg. Fixed Cost] 35
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Let’s Graph the Above Cost Items Contained in this Table 36
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Page 95 Table 6.3 Cost Relationships MC=min(ATC) and min(AVC) Vertical distance between ATC and AVC = AFC Input Use Cost ($) 37
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Key Revenue Concepts The following revenue concepts play key roles in determining where in Stage II a producer will want to produce Total Revenue (TR) =Multiplication of total amount of output produced by the sale price Average Revenue (AR) = Total revenue ÷ total amount of output produced Marginal Revenue (MR) = ∆ total revenue ÷ ∆ total amount of output produced How much revenue is generated by one additional unit of output? Under perfect competition, it is the per unit price 38
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Now let’s assume this firm can sell its product for $45/unit 39
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Page 98 Remember we are assuming perfect competition The firm takes price as given Price (Col. 2) = MR (Col. 7) What is the AR value? Key Revenue Concepts 40
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Page 98 With perfect competition, where would the firm maximize profit in the above example? Profit Maximization 41
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Let’s see this in graphical form 42
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Page 99 P=MR=AR $45 11.2 Profit maximizing Output where MR=MC 43
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The previous graph indicated that Profit is maximized at 11.2 units of output MR ($45) equals MC ($45) at 11.2 units of output Profit maximizing output occurs between points G and H At 11.2 units of output profit would be $190.40. Let’s do the math…. The previous graph indicated that Profit is maximized at 11.2 units of output MR ($45) equals MC ($45) at 11.2 units of output Profit maximizing output occurs between points G and H At 11.2 units of output profit would be $190.40. Let’s do the math…. Profit Maximization 44
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Profit at Price of $45? 28 P =45 $ Q 11.2 MC ATC AVC Revenue = $45 11.2 = $504.00 Total cost = $28 11.2 = $313.60 Profit = $504.00 – $313.60 = $190.40 Since P = MR = AR Average profit = $45 – $28 = $17 Profit = $17 11.2 = $190.40 45
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Profit at Price of $45? 28 P =45 $ Q 11.2 MC ATC AVC Revenue = $45 11.2 = $504.00 Total cost = $28 11.2 = $313.60 Profit = $504.00 – $313.60 = $190.40 Since P = MR = AR Average profit = $45 – $28 = $17 Profit = $17 11.2 = $190.40 Revenue = $45 11.2 = $504.00 Total cost = $28 11.2 = $313.60 Profit = $504.00 – $313.60 = $190.40 Since P = MR = AR Average profit = $45 – $28 = $17 Profit = $17 11.2 = $190.40 $190.40 46
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Page 99 P=MR=AR Zero economic profit if price falls to P BE Firm would only produce output O BE where AR (MR) ≥ ATC Zero economic profit if price falls to P BE Firm would only produce output O BE where AR (MR) ≥ ATC 47
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Profit at Price of $28? P=28 45 $ Q 11.210.3 MC ATC AVC Revenue = $28 10.3 = $288.40 Total cost = $28 10.3 = $288.40 Profit = $288.40 – $288.40 = $0 Since P = MR = AR Average profit = $28 – $28 = $0 Profit = $0 10.3 = $0 (break even) 48
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Page 99 P=MR=AR Firm can just cover variable cost if price falls to P SD. Firm would shut down if price falls below P SD Firm can just cover variable cost if price falls to P SD. Firm would shut down if price falls below P SD 49
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Profit at Price of $18? 28 P=18 45 $ Q 11.210.38.6 MC ATC AVC Revenue = $18 8.6 = $154.80 Total cost = $28 8.6 = $240.80 Profit = $154.80 – $240.80 = $0 Since P = MR = AR Average profit = $18 – $28 = –$10 Profit = –$10 8.6 = –$86 (Loss) 50
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Profit at Price of $10? 28 P=10 19 45 $ Q 11.210.38.6 MC ATC AVC 7.0 Revenue = $10 7.0 = $70.00 Total cost = $30 7.0 = $210.00 Profit = $70.00 – $210.00 = – $140.00 Since P = MR = AR Average profit = $10 – $30 = –$20 Profit = –$20 7.0 = –$140 Average variable cost = $19 Variable costs = $19 7.0 = $133.00 Revenue – variable costs = –$63 Not covering variable costs!!!!!! 51
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The Firm’s Supply Curve 28 10 18 45 $ Q 11.210.38.6 MC ATC AVC 7.0 52
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Page 99 We know that so long as P (= MR) > AVC some of the fixed costs can be covered Better economic position then shutting down altogether, WHY? We know that when P (= MR)=MC, the firm maximizes profit Portion of MC curve defined by output level that generates the minimum AVC is referred to as the firm’s supply curve The Firm’s Supply Curve 53
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The Firm’s Supply Curve 28 18 45 $ Q 11.210.38.6 ATC AVC Firm Supply Curve MC 54
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Now let’s look at the demand for a single input: Labor 55
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Key Input Relationships The following input-related derivations play key roles in determining amount of variable input to use to maximize profits Marginal Value Product (MVP) = MPP × Product Price MPP → ∆Output ÷ ∆Input Use Product Price → ∆$ ÷ ∆Output MVP → ∆$ ÷ ∆Input Use (Additional output value generated by the last increment in input use) Marginal Input Cost (MIC) = wage rate, rental rate, seed cost, etc. Page 100 56
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Page 101 5 B C E F G H J MVP=MPP x Output Price Wage rate is labor’s MIC I D 57
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Page 101 5 B C D E F G H I J Profit maximizing input use rule Use a variable input up to the point where Value received from another unit of input Equals cost of another unit of input → MVP=MIC 58
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Page 101 5 B C D E F G H I J The area below the green lined MVP curve and above the green lined MIC curve represents cumulative net benefit 59
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Page 100 MVP = MPP × $45 60
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Page 100 Profit are maximized where MVP = MIC or where MVP =$5 and MIC = $5 Profit are maximized where MVP = MIC or where MVP =$5 and MIC = $5 61
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Page 100 Marginal net benefit (Col. 5) = MVP (Col. 3) – labor MIC (Col. 4) = Value of additional output from last unit of input net of the cost of that input = – 62
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Page 100 The cumulative net benefit (Col. 6) of input use = the sum of successive marginal net benefits (Col. 5) = the grey area in previous graph. The cumulative net benefit (Col. 6) of input use = the sum of successive marginal net benefits (Col. 5) = the grey area in previous graph. 63
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Page 100 For example… $25.10 = $9.85 + $15.25 $58.35 = $25.10 + $33.25 For example… $25.10 = $9.85 + $15.25 $58.35 = $25.10 + $33.25 64
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Page 100 = – Cumulative net benefit is maximized where MVP=MIC at $5 65
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Page 101 5 B C D E F G H I J If you stopped at point E on the MVP curve, for example, you would be foregoing all of the potential profit lying to the right of that point up to where MVP=MIC. 66
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Page 101 5 B C D E F G H I J If you use labor beyond the point where MVP =MIC, you begin incurring losses as the return to another unit of labor is < $5.00, its per unit cost 67
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A Final Thought One final relationship needs to be made. The level of profit-maximizing output (O MAX ) in the graph on page 99 where MR = MC corresponds directly with the variable input level (L MAX ) in the graph on page 101 where MVP = MIC. Going back to the production function on page 88, this means that: O MAX = f(L MAX | capital, land and management) 68
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In Summary… Features of perfect competition Factors of production (Land, Labor, Capital and Management) Key decision rule: Profit maximized at output MR=MC Key decision rule: Profit maximized where MVP=MIC 69
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Chapter 7 focuses on the choice of inputs to use and products to produce…. 70
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