Technical rate of substitution
Summary
Technical rate of substitution
- \(y=f\left( x_1,x_2 \right)\) is a production function representing well behaved technology
- \(x_2=g\left( x_1 \right)\) is the equation of an isoquant
- The slope of the isoquant at \(\left( x_1,x_2 \right)\) is called the technical rate of substitution or the m arginal rate of technical substitution , \(TRS\) , of factor 2 for factor 1.
\[TRS= \frac{dx_2}{dx_1}=g'\left( x_1 \right)\]
- Technical rate of substitution for small changes in inputs:
\[TRS≈ \frac{Δx_2}{Δx_1}\]
- \(TRS\) measures the approximate increase in \(x_2\) , \(Δx_2\) , required to stay on the isoquant for a small increase in \(x_1\) by \(Δx_1\) .
- \(TRS\) is typically negative since \(Δx_2<0\) if \(Δx_1>0\)
- Example
- \(y=100\sqrt{x_1x_2}\)
- \(x_1=1\) and \(x_2=4\) produces \(y=200\)
- The isoquant for \(y=200\) has the equation \(x_2=g\left( x_1 \right)=4/x_1\)
\[TRS= \frac{dx_2}{dx_1}=- \frac{4}{x_1^2}=-4\]
- At \(\left( 1,4 \right)\) , if \(x_1\) is increased by \(Δx_1\) and \(x_2\) is reduced by four times as much , production will remain approximately constant .
- With (strictly) convex technology:
- \(TRS\) (strictly) increasing in \(x_2\)
- \(\left| TRS \right|\) (strictly) decreasing in \(x_2\)
- We have (strictly) diminishing technical rate of substitution
Marginal product and technical rate of substitution
- Important result:
\[TRS= \frac{dx_2}{dx_1}=- \frac{MP_1}{MP_2}\]
- Example
- \(y=100\sqrt{x_1x_2}\)
- \(x_1=1\) and \(x_2=4\) produces \(y=200\)
- The isoquant for \(y=200\) has the equation \(x_2=g\left( x_1 \right)=4/x_1\)
\[TRS= \frac{dx_2}{dx_1}=- \frac{4}{x_1^2}=-4\]
\[MP_1= \frac{50\sqrt{x_2}}{\sqrt{x_1}}=100\]
\[MP_2= \frac{50\sqrt{x_1}}{\sqrt{x_2}}=25\]
\[- \frac{MP_1}{MP_2}=- \frac{100}{25}=-4=TRS\]