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Learn about the two and three sector AE models, equilibrium in the AE model, and the multiplier effect. Understand how the AE model is used to predict and explain GDP.
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ECO 120 MacroeconomicsWeek 3 AE Model and the Multiplier Lecturer Dr. Rod Duncan
News • Wednesday 4-5pm tutorial has been moved from C2-213 to C2-216 starting tomorrow.
Topics • Two sector AE model • Three sector AE model • Equilibrium in the AE model • The multiplier in the AE model
What the AE model for? • Always try to see the forest for the trees! • Always ask “what is this for?” “what is the purpose of this model?” • The aggregate expenditure (AE) model is a simple model of GDP: • It can be used to predict what GDP will do? Is Australian GDP rising? How fast? • It can be used to explain what happened to GDP? For example GDP might be rising because net exports are rising.
The big picture P, Wealth, H/h Expectations, H/h Taxes C P, i, Business Expectations, Business Taxes I AE AD Government policy, and? G NX P, and?
Consumption function • The consumption function relates the level of private household consumption of goods and services (C) to the level of aggregate income (Y). • We can represent the consumption function in three different and equivalent ways. • An mathematical equation • A graph • A table • For example the consumption function could be: • C = $100bn + 0.5Y
Consumption function • We can represent this same function with a graph. C C(Y) = $100bn + 0.5Y $150bn Slope is 0.5 $100bn The MPC is 0.5 Y $100bn
Consumption function • Or we can represent the same function with a table. • Three ways of represent-ing the same function.
Two sector model • Aggregate expenditure (AE) in the two sector model is composed of consumption (C) and investment (I). AE = C + I • In this model, we treat I as exogenous, so it is a constant. • Let’s use the same simple linear consumption function: C = 100 + 0.5Y I = 100 AE = C + I = 100 + 0.5Y + 100 = 200 + 0.5Y
Aggregate expenditure function • This equation is a relationship between income (Y) and aggregate expenditure (AE). AE = 200 + 0.5Y $250bn Slope is 0.5 $200bn Y $100bn
Aggregate expenditure function • But we could also use the table form.
Equilibrium in two sector model • Equilibrium in a model is a situation of “balance”. In our AE model, equilibrium requires that demand for goods (AE) is equal to supply of goods (Y). Y = AE = C + I • For the equilibrium we are looking for the value of GDP, Y*, such that goods demand and goods supply are equal. • In our two sector AE model that means that we can look up our AE table and find where AE = Y. • The equilibrium value of Y will be our prediction of GDP for our AE model.
Equilibrium • The equilibrium value of GDP is $400bn.
Equilibrium • We could accomplish the same by using our graph of the AE function. • The AE line shows us the level of goods demand for each value of Y. • The 45 degree line represents the value of Y or supply of goods. • Equilibrium will occur when the 45 degree line and the AE line cross. At the crossing, goods demand is equal to goods supply for that level of Y.
Equilibrium • The equilibrium value of Y is where the 45 degree line and the AE line cross. Y* is at $400bn. Y AE = 200 + 0.5Y 400 Y 400
Equilibrium • Finally, if you are comfortable with the mathematics, you can solve for the equilibrium value of Y using the equations: Y* = AE = 200 + 0.5Y* Y* – 0.5Y* = 200 0.5Y* = 200 Y* = 400 • You arrive at the same answer no matter which way you use to derive it.
Autonomous expenditure • In our model we have two part of aggregate expenditure: AE = $200bn + 0.5Y • One part does not depend on the value of Y- the $200bn. This portion is called “autonomous expenditure”. • The other part does depend on the value of Y- the 0.5Y. • In our model part of autonomous expenditure is C and part is I.
Scenario: Investment falls • What happens if I drops from 100 to 50 perhaps because of uncertainty due to terrorism scares? • Equilibrium GDP drops to 300.
Scenario • But you could also find the same answer with some algebra: AE = C + I = 100 + 0.5Y + 50 = 150 + 0.5Y Y* = AE = 150 + 0.5Y* Y* – 0.5Y* = 150 0.5Y* = 150 Y* = 300 • Find the answer in the way you feel most comfortable.
Multiplier • So a $50bn drop in investment (or autonomous expenditure) leads to a $100bn drop in equilibrium GDP. • The ratio of the change in GDP over the change in autonomous expenditure is called the multiplier: Multiplier = (Change in GDP)/(Change in I)
Multiplier • In our scenario the multiplier is: Multiplier = $100bn / $50bn = 2 • This term is given the name “multiplier” because each $1 change in I lead to a 2x$1 change in GDP. • We will come back to the multiplier after we talk about the three sector model.
Three sector AE model • Now we make our model slightly more complicated by bringing in the government. The government has two effects on our model: • The government raises tax revenues (T) by taxing household incomes. • The government purchases some goods and services for government consumption (G). • We treat the levels of T and G as exogenous to our AE model. Government policy determines what T and G will be, and policy is not affected by the equilibrium level of GDP.
Three sector model • Household consumption depended on household income, Y, in our two sector model. • In the three sector model, the income that households have available to spend or save is now income net of taxes, Y – T. We call this amount “disposable income”, YD. • The consumption function will now depend on disposable income, not income. C = C(Y – T) = C(YD)
Three sector model • Our new aggregate expenditure function includes government purchases of goods and services, so we have: AE = C + I + G • Let’s assume we have the same linear consumption function as before, but now in disposable income: C = 100 + 0.5 (Y – T) • Let T = G = 50 and let I = 100. We can follow the same steps as before to find our AE function and then to find equilibrium GDP.
Aggregate expenditure function • Our AE function is: AE = C(Y – T) + I + G AE = 100 + 0.5(Y – 50) + 100 + 50 AE = 100 + 0.5Y – 25 + 100 + 50 AE = 225 + 0.5Y • We can also represent this as a table. Our C function with disposable income is: C = 100 + 0.5(Y-50) = 75 + 0.5Y
Equilibrium • If we want to find equilibrium GDP in our three sector model, we need to find the level of GDP, Y*, for which goods demand (AE) is equal to goods supply (Y). • If we look at our table, we see that for an income level of Y of 400, AE is 425 which exceeds Y. At an income level of Y of 500, AE is 475 which is less than Y. • We would guess that the equilibrium value of Y lies between 400 and 500. • We construct a new table of values of Y between 400 and 500.
Equilibrium • The equilibrium value of Y is 450. • We could find the answer with our equations: AE = 225 + 0.5Y Y* = AE = 225 + 0.5Y* Y* - 0.5Y* = 225 0.5Y* = 225 Y* = 450
Scenario: Investment falls • What happens if we have the same drop in investment in the three sector model? So I drops from 100 to 50? • Using our equations: AE = 100 + 0.5(Y - T) + I + G AE = 75 + 0.5Y + 50 + 50 AE = 175 + 0.5Y • Solving for Y*, we get: Y* = AE = 175 + 0.5Y* Y* = 350 • Our multiplier = 100/50 = 2 as before.
Generalizing the AE model • In all our models, we have had Y (and also C) as our endogenous variable. • Exogenous variables are variables in a model that are determined “outside” the model itself, so they appear as constants. • For the aggregate expenditure model, we treat as exogenous: • Investment (I) • Government consumption (G) ( three sector) • Taxes (T) (three sector) • Net Exports (NX) (four sector)
Aggregate expenditure • In a two sector model: AE = C(Y) + I • In a closed (no foreign trade) economy or three sector model: AE = C(Y - T) + I + G • In an open economy or four sector model: AE = C(Y - T) + I + G + NX • Changes in the exogenous variables (I, G, T or NX) will shift the AE curve.
Equilibrium in the AE model • Exogenous variables are just constants- numbers. • Supply of goods equals demands of goods (in the closed economy): Y = C + I + G Y = a + b(Y – T) + I + G (1 – b)Y = a – bT + I + G • Finally we get:
Equilibrium • The value 1/(1-b) is the multiplier in our AE model. • So if I or G changes by 1, we know that Y will change by 1/(1-b). • The constant b here is just the MPC. • So we have: Multiplier = 1 / (1 – MPC) • In our simple linear model, b was 0.5, and we get: Multiplier = 1 / (1 – 0.5) = 1/0.5 = 2
Expenditure multiplier • Imagine the government wishes to affect the economy. One tool available is government consumption, G, or government taxes, T. This is called “fiscal policy”. • Any change in G (∆G) in our AE model will produce:
Multiplier • If b=0.75, then the multiplier is (1/0.25) or 4, so $1 of new G will produce $4 of new Y. • Our multiplier is equal to 1/(1-MPC). • Since 0<MPC<1, our multiplier will be greater than 1. • The larger is the MPC, the larger is our multiplier.
Practice exam question The Howard government plans to spend $600m on new coast guard ships for the Australian armed forces. These ships will be built in Tasmania. Explain (using both a diagram and text based on what you have learned so far in class) how the Australian economy will be affected by: [Hints: Remember to draw the initial equilibrium before the new spending and new taxes on your diagrams. Treat the new taxes and new spending as separate policies.] (a) the $600m in new government purchases; and (b) the $600m in new income taxes the government will have to use to pay for the ships.
