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In macroeconomics, a multiplier is a factor of proportionality that measures how much an endogenous variable changes in response to a change in some exogenous variable.

For example, suppose variable x changes by k units, which causes another variable y to change by M × k units. Then the multiplier is M.

Two multipliers are commonly discussed in introductory macroeconomics.

Commercial banks create money, especially under the fractional-reserve banking system used throughout the world. In this system, money is created whenever a bank gives out a new loan. This is because the loan, when drawn on and spent, mostly finishes up as a deposit back in the banking system and is counted as part of money supply. After putting aside a part of these deposits as mandated bank reserves, the balance is available for the making of further loans by the bank. This process continues multiple times, and is called the multiplier effect.

The multiplier may vary across countries, and will also vary depending on what measures of money are being considered. For example, consider M2 as a measure of the U.S. money supply, and M0 as a measure of the U.S. monetary base. If a $1 increase in M0 by the Federal Reserve causes M2 to increase by $10, then the money multiplier is 10.

Multipliers can be calculated to analyze the effects of fiscal policy, or other exogenous changes in spending, on aggregate output.

For example, if an increase in German government spending by €100, with no change in tax rates, causes German GDP to increase by €150, then the spending multiplier is 1.5. Other types of fiscal multipliers can also be calculated, like multipliers that describe the effects of changing taxes (such as lump-sum taxes or proportional taxes).

Keynesian economists often calculate multipliers that measure the effect on aggregate demand only. (To be precise, the usual Keynesian multiplier formulas measure how much the IS curve shifts left or right in response to an exogenous change in spending.)

American Economist Paul Samuelson credited Alvin Hansen for the inspiration behind his seminal 1939 contribution. The original Samuelson multiplier-accelerator model (or, as he belatedly baptised it, the "Hansen-Samuelson" model) relies on a multiplier mechanism that is based on a simple Keynesian consumption function with a Robertsonian lag:

${\displaystyle C_{t}=C_{0}+cY_{t-1}}$

${\displaystyle 1/(1-c(1-t)+m)}$

so present consumption is a function of past income (with c as the marginal propensity to consume). Here, t is the tax rate and m is the ratio of imports to GDP. Investment, in turn, is assumed to be composed of three parts:

${\displaystyle I_{t}=I_{0}+I(r)+b(C_{t}-C_{t-1})}$

The first part is autonomous investment, the second is investment induced by interest rates and the final part is investment induced by changes in consumption demand (the "acceleration" principle). It is assumed that b > 0. As we are concentrating on the income-expenditure side, let us assume I(r) = 0 (or alternatively, constant interest), so that:

${\displaystyle I_{t}=I_{0}+b(C_{t}-C_{t-1})}$

Now, assuming away government and foreign sector, aggregate demand at time t is:

${\displaystyle Ytd=C_{t}+I_{t}=C_{0}+I_{0}+cY_{t-1}+b(C_{t}-C_{t-1})}$

assuming goods market equilibrium (so ${\displaystyle Y_{t}=Ytd}$), then in equilibrium:

${\displaystyle Y_{t}=C_{0}+I_{0}+cY_{t-1}+b(C_{t}-C_{t-1})}$

But we know the values of ${\displaystyle C_{t}}$ and ${\displaystyle C_{t-1}}$ are merely ${\displaystyle C_{t}=C_{0}+cY_{t-1}}$ and ${\displaystyle C_{t-1}=C_{0}+cY_{t-2}}$ respectively, then substituting these in:

${\displaystyle Y_{t}=C_{0}+I_{0}+cY_{t-1}+b(C_{0}+cY_{t-1}-C_{0}-cY_{t-2})}$

or, rearranging and rewriting as a second order linear difference equation:

${\displaystyle Y_{t}-(1+b)cY_{t-1}+bcY_{t-2}=(C_{0}+I_{0})}$

The solution to this system then becomes elementary. The equilibrium level of Y (call it ${\displaystyle Y_{p}}$, the particular solution) is easily solved by letting ${\displaystyle Y_{t}=Y_{t-1}=Y_{t-2}=Y_{p}}$, or:

${\displaystyle (1-c-bc+bc)Y_{p}=(C_{0}+I_{0})}$

so:

${\displaystyle Y_{p}=(C_{0}+I_{0})/(1-c)}$

The complementary function, ${\displaystyle Y_{c}}$ is also easy to determine. Namely, we know that it will have the form ${\displaystyle Y_{c}=A_{1}r_{1}t+A_{2}r_{2}t}$ where ${\displaystyle A_{1}}$ and ${\displaystyle A_{2}}$ are arbitrary constants to be defined and where ${\displaystyle r_{1}}$ and ${\displaystyle r_{2}}$ are the two eigenvalues (characteristic roots) of the following characteristic equation:

${\displaystyle r^{2}-(1+b)cr+bc=0}$

Thus, the entire solution is written as ${\displaystyle Y=Y_{c}+Y_{p}}$

Opponents of Keynesianism have sometimes argued that Keynesian multiplier calculations are misleading; for example, according to the theory of Ricardian equivalence, it is impossible to calculate the effect of deficit-financed government spending on demand without specifying how people expect the deficit to be paid off in the future. ^{[citation needed]}

The three most known multiplier formula are as depicted, where:

• G stands for government spending
• T for taxation
• Y for nominal GDP
• I for private investment
• X for exports
• c for propensity to consume
• s for propensity to save
• m for propensity to import

Multipliers in an open economy

	Keynesian multiplier	Fiscal multiplier driven by an increase in tax	Fiscal multiplier driven by tax cuts
The multiplier's characteristics	$${\displaystyle \Delta G>0\ ;\Delta T=0}$$	$${\displaystyle \Delta G>0\ ;\Delta G=\Delta T}$$	$${\displaystyle \Delta T<0\ ;\Delta G=0}$$
Formula	$${\displaystyle \Delta Y={1 \over s+m}\cdot (\Delta I+\Delta G+\Delta X)}$$	$${\displaystyle \Delta Y={s \over s+m}\cdot \Delta G+{1 \over s+m}\cdot (\Delta I+\Delta X)}$$	$${\displaystyle \Delta Y={c \over s+m}\cdot \Delta (-T)+{1 \over s+m}(\Delta I+\Delta G+\Delta X)}$$
Multiplier given	$${\displaystyle {1 \over s+m}}$$	$${\displaystyle {s \over s+m}}$$	$${\displaystyle {c \over s+m}}$$

The general method for calculating short-run multipliers is called comparative statics. That is, comparative statics calculates how much one or more endogenous variables change in the short run, given a change in one or more exogenous variables. The comparative statics method is an application of the implicit function theorem.

Dynamic multipliers can also be calculated. That is, one can ask how a change in some exogenous variable in year t affects endogenous variables in year t, in year t+1, in year t+2, and so forth.^[1] A graph showing the impact on some endogenous variable, over time (that is, the multipliers for times t, t+1, t+2, etc.), is called an impulse-response function.^[2] The general method for calculating impulse response functions is sometimes called comparative dynamics.

The Tableau économique (Economic Table) of François Quesnay (1758), which laid the foundation of the Physiocrat school of economics is credited as the "first precise formulation" of interdependent systems in economics and the origin of multiplier theory.^[3] In the tableau économique, one sees variables in one period (time t) feeding into variables in the next period (time t+1), and a constant rate of flow yields geometric series, which computes a multiplier.

The modern theory of the multiplier was developed in the 1930s, by Kahn, Keynes, Giblin, and others,^[4] following earlier work in the 1890s by the Australian economist Alfred De Lissa, the Danish economist Julius Wulff, and the German-American economist N. A. J. L. Johannsen.^[5]

• Complex multiplier
• Local multiplier effect
• Multiplier uncertainty
• Social Multiplier Effect