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<h1 class="post-title">Models of Production</h1>
<p class="post-meta">
<time datetime="2024-06-22">22/06/2024</time>
</p>
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<article class="post-article">
<h2>solow</h2>
<div class="fold"><h3>introduction</h3></div>
<div>
<p>
The Solow Model is an economic model of production that
incorporates the incorporates the idea of capital accumulation.
Based on the
<a
target="blank"
href="https://en.wikipedia.org/wiki/Cobb%E2%80%93Douglas_production_function"
>Cobb-Douglas production function</a
>, the Solow Model describes production as follows:
\[Y_t=F(K_t,L_t)=\bar{A}K_t^\alpha L_t^{1-\alpha}\] With:
</p>
<ul>
<li>\(\bar{A}\): total factor productivity (TFP)</li>
<li>
\(\alpha\): capital&apos;s share of output&mdash;usually \(1/3\)
based on
<a target="blank" href="https://arxiv.org/pdf/1105.2123"
>empirical data</a
>
</li>
</ul>
<p>
In this simple model, the following statements describe the
economy:
</p>
<ol>
<li>
Output is either saved or consumed; in other words, savings
equals investment
</li>
<li>
Capital accumulates according to investment \(I_t\) and
depreciation \(\bar{d}\), beginning with \(K_0\) (often called
the
<u>Law of Capital Motion</u>)
</li>
<li>Labor \(L_t\) is time-independent</li>
<li>
A savings rate \(\bar{s}\) describes the invested portion of
total output
</li>
</ol>
<p>
Including the production function, these four ideas encapsulate
the Solow Model:
</p>
<div style="display: flex; justify-content: center">
<div style="padding-right: 50px">
<ol>
<li>\(C_t + I_t = Y_t\)</li>
<li>\(\Delta K_{t+1} = I_t - \bar{d} K_t\)</li>
</ol>
</div>
<div style="padding-left: 50px">
<ol start="3">
<li>\(L_t = \bar{L}\)</li>
<li>\(I_t = \bar{s} Y_t\)</li>
</ol>
</div>
</div>
</div>
<div class="fold">
<h3>solving the model</h3>
</div>
<div>
<p>
Visualizing the model, namely output as a function of capital,
provides helpful intuition before solving it.
</p>
<p>
Letting \((L_t,\alpha)=(\bar{L}, \frac{1}{3})\), it follows that
\(Y_t=F(K_t,L_t)=\bar{A}K_t^{\frac{1}{3}} \bar{L}^{\frac{2}{3}}\).
Utilizing this simplification and its graphical representation
below, output is clearly characterized by the cube root of
capital:
</p>
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<li>
<div class="slider">
<label for="sliderA">\(A:\)</label>
<span id="outputA">1.00</span>
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type="range"
id="sliderA"
min="0.1"
max="2"
step="0.01"
value="1"
/>
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</li>
<li>
<div class="slider">
<label for="sliderD">\(d:\)</label>
<span id="outputD">0.50</span>
<input
type="range"
id="sliderD"
min="0.01"
max="1"
step="0.01"
value="0.50"
/>
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</li>
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<li>
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<label for="sliderS">\(s:\)</label>
<span id="outputS">0.50</span>
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type="range"
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min="0.01"
max="1"
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value="0.50"
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<label for="sliderAlpha">\(\alpha:\)</label>
<span id="outputAlpha">0.33</span>
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type="range"
id="sliderAlpha"
min="0.01"
max="1"
step="0.01"
value="0.33"
/>
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</div>
<p>
When investment is completely disincentivized by depreciation (in
other words, \(sY_t=\bar{d}K_t\)), the economy equilibrates at a
so-called &quot;steady-state&quot; with equilibrium
\((K_t,Y_t)=(K_t^*,Y_t^*)\).
</p>
<p>
Using this equilibrium condition, it follows that:
\[Y_t^*=\bar{A}{K_t^*}^\alpha\bar{L}^{1-\alpha} \rightarrow
\bar{d}K_t^*=\bar{s}\bar{A}{K_t^*}^\alpha\bar{L}^{1-\alpha}\]
\[\rightarrow
K^*=\bar{L}(\frac{\bar{s}\bar{A}}{\bar{d}})^\frac{1}{1-\alpha}\]
\[\rightarrow
Y^*=\bar{A}^\frac{1}{1-\alpha}(\frac{\bar{s}}{\bar{d}})^\frac{\alpha}{1-\alpha}\bar{L}\]
</p>
<p>
Thus, the equilibrium intensive form (output per worker) of both
capital and output are summarized as follows:
\[(k^*,y^*)=(\frac{K^*}{\bar{L}},\frac{Y^*}{\bar{L}})
=((\frac{\bar{s}\bar{A}}{\bar{d}})^\frac{1}{1-\alpha},
\bar{A}^\frac{1}{1-\alpha}(\frac{\bar{s}}{\bar{d}})^\frac{\alpha}{1-\alpha})\]
</p>
</div>
<div class="fold"><h3>analysis</h3></div>
<p>discuss limitations</p>
<h2>romer</h2>
<h2>romer-solow</h2>
</article>
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