MIDTERMM
THE PRODUCTION FUNCTION AND GROWTH
In this note I’ll lay out the analytics of a surplus producing economy. The presentation
relies heavily on the ideas of the classical political economists, specifically the insights of Adam
Smith, David Ricardo, and Karl Marx. To keep things simple we’ll imagine a closed economy,
that is, an economy that does not engage in trade with other economies or involved in an
exploitative or subordinate relation with other systems. It is, in short, a self-contained system.
This assumption is commonly adopted in economics because it helps to focus attention on the
factors that are particular to the system and not the result of outside influence. Once the
characteristics of the system are understood, we can enlarge the analysis to include international
trade, imperialism, or dependency, without destroying the principles captured in the simpler case
of a closed economy.
We’ll start by exploring the relationship between work and gross output. With a given
productive capacity and work environment, that is with a given amount and quality of capital and
land and a given set of work habits and expectations, applying more labor to the production
process will cause output to grow at a diminishing rate. Figure 1A.1 provides a visual
representation of this idea.
Gross output (Q) is measured on the vertical axis, while number of workers (N) is
measured on the horizontal axis. The Q curve, also referred to as a production function, shows
how the existence of diminishing returns causes output to grow at a diminishing rate as a result
of adding more workers to production. But rather than thinking of the production function as a
visual image of a growing economy, the proper interpretation is that it represents the range of
production that’s possible given existing conditions. It provides a visual representation of the
relationship between labor usage and output per time period, given existing conditions of
2
production and work. Economic growth, on the other hand, involves additions or improvements
to the system’s productive capacity, causing the system’s productive capacity to grow and the
entire production function to shift over time.
Figure 1A.1
The production function assumes that laborers are working at the same level of intensity.
As a result, the diminishing nature of extra output is not the result of declining effort, but rather
the result of having to interact with increasingly less fertile land. It should also be noted that the
workers measured on the horizontal axis are all assumed to be direct workers; there is no
overhead labor. The graph could be amended to incorporate the role of overhead labor, but it
would complicate the presentation without improving our understanding of basic economic
principles. It should also be noted that all labor is assumed to be productive. There is, in other
words, no unproductive labor.
Given the above production function, let’s say that N’ workers are currently being used
per time period. This would mean that the economy is generating Q’ amounts of gross output per
time period. The worker’s replenishment, socially necessary consumption, is Cn’, depreciation is
Dp (the difference between NP’ and Cn’), and the system’s necessary product is NP’. The
3
difference between gross output (Q’) and the necessary product (NP’) represents the system’s
surplus product. The surplus product represents the amount that’s available for surplus
consumption and/or net investment (not shown in the graph). Obviously, the work force must
generate a surplus beyond its own necessary consumption to provide for the consumption
standards of other classes of people, its own possible surplus consumption, depreciation and net
investment. The extent to which this occurs and how the surplus is distributed and used depends
not simply on the productivity of labor but on the political organization of society.
The historical pattern, for surplus producing systems, is to find one class of people
controlling the laboring activities of another class of people – those who do the work. While
there are variations on this theme and classes of people who fall in between these two categories;
it’s nevertheless the case the surplus producing economies have traditionally been class divided
societies with one class of people, the managing or ruling classes, directing or controlling the
laboring activities of the laboring classes. What’s more, the ruling classes oversees the laboring
effort of the workers to ensure that the surplus that’s generated by the workers is used for their
own consumption and/or invested in more productive capacity. They have a direct interest in
ensuring that the workers generate a surplus that’s sufficient to sustain their lifestyle; as a result,
they will generally be intent on having the workers produce as much of a surplus as they possibly
can.
A numerical counterpart to the above graph is presented in Table 1A.1 (the numbers are
provided for heuristic purposes; they are not intended to capture the actual proportions found in
real economies). For the moment, focus on the first six columns of the table. The columns N and
Q are the numerical counterpart to the production function in Figure 1A.1, showing that, with a
given productive capacity and working environment, more workers will bring about greater
4
output, but at a diminishing rate. The Cn column represents the socially necessary consumption
of the various workers (represented as line Cn in Figure 1A.1), while the Dp column represents
depreciation (shown in Figure 1A.1 as the difference between the Cn+Dp line and the Cn line).
The sum of Cn and Dp is the system’s necessary product (NP) and is represented as the Cn+Dp
line in Figure 1A.1. The column labeled SP represents the system’s surplus product and is the
difference between gross output (Q) and the necessary product (NP).
N Q Cn Dp NP SP ap mp cn NP/N SP/N
0 0 0.00 6.00 6.00 -6.00 8
1 14 8.00 6.00 14.00 0.00 14.00 14.00 8 14.00 0.000
2 27 16.00 6.00 22.00 5.00 13.50 13.00 8 11.00 2.500
3 39 24.00 6.00 30.00 9.00 13.00 12.00 8 10.00 3.000
4 50 32.00 6.00 38.00 12.00 12.50 11.00 8 9.50 3.000
5 60 40.00 6.00 46.00 14.00 12.00 10.00 8 9.20 2.800
6 69 48.00 6.00 54.00 15.00 11.50 9.00 8 9.00 2.500
7 77 56.00 6.00 62.00 15.00 11.00 8.00 8 8.86 2.143
8 84 64.00 6.00 70.00 14.00 10.50 7.00 8 8.75 1.750
9 90 72.00 6.00 78.00 12.00 10.00 6.00 8 8.67 1.333
10 95 80.00 6.00 86.00 9.00 9.50 5.00 8 8.60 0.900
Note that as the employment of labor increases, with a given productive capacity and
work environment, the system’s surplus product grows, reaches a maximum, and then declines.
This can also be seen in Figure 1A.1, by noting that the vertical distance between the production
function (Q) and the necessary product (line Cn+Dp) at first grows, reaches a maximum, then
declines. This behavior is due to the combined effect of both diminishing returns and a growing
necessary product. Adding more workers to the production process, and assuming a stable work
environment, will cause output to grow at a diminishing rate while causing the necessary product
to grow at a constant rate. The interaction of these two trends causes the surplus product to grow,
reach a maximum, and eventually become zero (not shown in either the graph or the table, but
implied in both by the fact that the size of the surplus begins to diminish).
5
Another way of thinking about this is that there’s a maximum amount of surplus the labor
force is capable of generating, given productive capacity and work conditions. That is, given the
amount and quality of capital and land, and existing work habits, the system is designed to
generate a maximum surplus with a specific number of workers. In the table that number of
workers is 7; that is, given the system’s productive capacity and work habits, seven workers will
produce the most surplus. Adding more workers beyond that amount will still generate a surplus,
but not as much as the system was designed for. Of course, a smaller number of workers will
also generate smaller surpluses. In Figure 1A.1, the number of workers which will generate a
maximum surplus is N’.
All of this can be interpreted on a per worker basis. Since the workers are the producers
of the gross product, we can interpret the above relationships by comparing the amount that the
average worker produces to the amount the average worker uses up in consumption. Columns
seven through eleven in Table 1A.1 (from column ap to column SP/N), show these relationships.
The column labeled ap represents the average productivity of labor and measures the
amount of gross output produced by the average worker. Thus, when 5 workers are used and
gross output is 60, the productivity of labor is 12 (60 divided by 5). The column labeled mp
represents the marginal productivity of labor and measures the amount of extra output generated
by using one more worker. For example, when the number of workers increases from 2 to 3 per
time period, gross output increases from 27 to 39 per time period; that is, the addition of the third
worker causes output to grow by 12. The marginal product, mp, of the third worker must
therefore be 12. The column labeled cn represents the socially necessary consumption per
worker, which in this simple example is 8 units of gross output per worker. When this level of
consumption per worker is multiplied by the number of workers we arrive at a measure of
6
socially necessary consumption (Cn) for the system as a whole. The NP/N column measures the
system’s necessary product per worker (NP divided by N). Note that as the usage of labor
increases necessary product per worker gradually declines because the fixed amount of
depreciation is spread over a larger number of workers. The SP/N column measures the system’s
surplus product per worker (SP divided by N). Figure 1A.2 provides the visual counterpart to
these ideas.
Figure 1A.2
The ap line represents the productivity of labor. Note that, as in the table, it shows the
productivity of labor declining as more labor is applied to existing productive capacity. Once
again, this is not due to a failing on the part of the workers but rather to the existence of
diminishing returns. The mp line represents the marginal productivity of labor. Note that the
marginal productivity of labor is declining at a faster pace than the average productivity of labor.
Socially necessary consumption per worker is shown as the straight line labeled cn. The
necessary product per worker is shown as a gradually declining curve (cn+Dp/N) that lies above
the cn line; this is the visual counterpart to the NP/N column in Table 1A.1.
7
The marginal productivity of labor has a special role to play in our understanding of the
surplus. In looking over Table 1A.1 it should be apparent that the surplus product, SP, reaches a
maximum when 7 workers are employed. Note that it’s also at that point that the marginal
productivity of labor (mp) is equal to socially necessary consumption per worker (cn). This is an
important principle of economics. The basic idea is that the surplus product will reach a
maximum when the extra output generated by one more worker (mp) is just equal to (or greater
than, but close to) the extra cost of using one more worker (cn). Note that in Figure 1A.2, the
point at which the marginal product of labor line intersects the consumption per worker line is
comparable to using 7 workers in Table 1A.1. In Figure 1A.2, that point occurs when N’ workers
are used; the surplus product is at a maximum at that point.
When N’ workers are used, average productivity is ap’, socially necessary consumption
per worker is cn’ and necessary product per worker is NP/N’. Note that the difference between
the productivity of labor (ap) and socially necessary consumption per worker (cn) represents the
amount in excess of the average worker’s consumption that is used by the rest of society for
depreciation, surplus consumption, or net investment. The proportions in which the surplus is
used for these various purposes depends on the nature of society’s technology and political
economic institutions. But it should be obvious from the graph that, beyond some point, the
excess that’s generated by the average worker will start to diminish and eventually be just
enough to cover depreciation, leaving nothing for surplus consumption or net investment. Of
course, one would not expect society to consciously reach such a state of affairs. Those who live
off the surplus, the ruling classes, would begin to search for new technologies and/or new
productive capacity in the hope of improving the productivity of labor and increasing the size of
8
the surplus. Indeed, the pressure to search for alternative methods of generating more surpluses
will begin to occur when more than N’ workers are employed.
Figure 1A.3 provides a visual image of the impact of capital accumulation on economic
growth. The figure assumes that there are only two eras or phases. The first one, corresponding
to production function Q, shows the relationship between number of workers and gross output
with the initial productive capacity. The second one, corresponding to production function Q’,
shows the relationship between number of workers and gross output with an enhanced
productive capacity due to capital accumulation.
Figure 1A.3
The figure shows depreciation increasing with the process of capital accumulation, both
in absolute terms and as a fraction of gross output. The existence of more capital has had the
effect of increasing the amount of gross product that has to be allocated to capital replenishment.
However, the extent to which this occurs depends on the nature of capital accumulation. We will
consider the types of capital accumulation later on, but for the moment it’s enough to know that
the rate and level of depreciation can vary and need not take the form suggested in Figure 1A.3,
even though it is not uncommon.
9
Figure 1A.4 provides the per worker counterpart to Figure 1A.3. Note that, when seen
from this perspective, the process of capital accumulation has the effect of improving the
productivity of labor; the line labeled ap’ represents the greater range of productivity brought on
by the accumulation of capital. The process of capital accumulation would also affect the
marginal productivity of labor. In general, and once again depending on the nature of
technological change, the marginal productivity of labor would increase in tandem with the
average productivity of labor. However, for ease of exposition (to keep the figure relatively
uncluttered), the marginal productivity of labor (mp) is not shown.
Figure 1A.4 also shows, consistent with Figure 1A.3 a greater level of depreciation, and
thus a greater necessary product. But the improvement in labor productivity and thus gross
output is, at a minimum, equal to the growth in necessary product.
Figure 1A.4