Revisions to Derivation of the Ideal Price Index

deleted 2 characters in body

Source Link

edited Jun 11 at 17:11

12.8k
10
37

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{1 - \varepsilon}} = 1. $$$$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{\varepsilon-1}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_L Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_H Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{1 - \varepsilon}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_L Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_H Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{\varepsilon-1}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_L Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_H Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

typos

Source Link

edited Jun 10 at 13:16

tdm

12.8k
10
37

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{1 - \varepsilon}{\varepsilon}} = 1. $$$$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{1 - \varepsilon}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_H Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_L Y_L^{-1/\varepsilon}. \end{align*} $$$$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_L Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_H Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{1 - \varepsilon}{\varepsilon}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_H Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_L Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{\varepsilon}{1 - \varepsilon}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_L Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_H Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

Source Link

created Jun 10 at 6:06

tdm

12.8k
10
37

The price index is given by $c(p_L, p_H,1)$ which is the minimal cost of producing 1 unit of output. It is given by: $$ \min p_L Y_L + p_H Y_H \text{ s.t. } \left[\gamma_L Y_L^{(\varepsilon -1)/\varepsilon} + \gamma_H Y_H^{(\varepsilon-1)/\varepsilon}\right]^{\frac{1 - \varepsilon}{\varepsilon}} = 1. $$ The first order conditions give: $$ \begin{align*} &p_L = \lambda Y^{-1} \gamma_H Y_H^{-1/\varepsilon}\\ &p_H = \lambda Y^{-1} \gamma_L Y_L^{-1/\varepsilon}. \end{align*} $$ This gives: $$ Y_H = \left(\frac{p_L}{p_H}\right)^\varepsilon \left(\frac{\gamma_H}{\gamma_L}\right)^\varepsilon Y_L. $$ Substituting into the constraint gives: $$ Y_L = \gamma_L^{\varepsilon} p_L^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}.\\ Y_H = \gamma_H^{\varepsilon} p_H^{-\varepsilon} \left[\gamma_L^\varepsilon p_L^{1- \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon} \right]^{-\frac{\varepsilon}{\varepsilon-1}}. $$ As such, $$ c(p_L, p_H, 1) = p_L Y_L + p_H Y_H = \left[\gamma_L^\varepsilon p_L^{1 - \varepsilon} + \gamma_H^\varepsilon p_H^{1 - \varepsilon}\right]^{\frac{1}{\varepsilon - 1}}. $$

Stack Exchange Network

Return to Answer