Alfred Weber

For the Swiss politician, see Alfred Weber (Swiss politician).
Alfred Weber
Born (1868-07-30)30 July 1868
Erfurt, Prussian Saxony
Died 2 May 1958(1958-05-02) (aged 89)
Heidelberg, Baden-Württemberg

Alfred Weber (30 July 1868 2 May 1958) was a German economist, geographer, sociologist and theoretician of culture whose work was influential in the development of modern economic geography.

Life

Born in Erfurt and raised in Charlottenburg.

From 1907 to 1933, Weber was a professor at the University of Heidelberg.

Work

Weber supported reintroducing theory and causal models to the field of economics, in addition to using historical analysis. In this field, his achievements involve work on early models of industrial location. He lived during the period when sociology became a separate field of science.

Weber maintained a commitment to the "philosophy of history" traditions. He contributed theories for analyzing social change in Western civilization as a confluence of civilization (intellectual and technological), social processes (organizations) and culture (art, religion, and philosophy).

Least cost theory

Leaning heavily on work developed by the relatively unknown Wilhelm Launhardt, Alfred Weber formulated a least cost theory of industrial location which tries to explain and predict the locational pattern of the industry at a macro-scale. It emphasizes that firms seek a site of minimum transport and labor cost.

The point for locating an industry that minimizes costs of transportation and labor requires analysis of three factors:

Material index

The point of optimal transportation is based on the costs of distance to the "material index" – the ratio of weights of the intermediate products (raw materials) to the finished product.

In one scenario, the weight of the final product is less than the weight of the raw material going into making the product—the weight losing industry. For example, in the copper industry, it would be very expensive to haul raw materials to the market for processing, so manufacturing occurs near the raw materials. (Besides mining, other primary activities (or extractive industries) are considered material oriented: timber mills, furniture manufacture, most agricultural activities, etc.. Often located in rural areas, these businesses may employ most of the local population. As they leave, the locale area loses its economic base.)

In the other, the final product is equally as heavy (Material Index is equal to 1) as the raw materials that require transport. Usually this is a case of some ubiquitous raw material, such as water, being incorporated into the product. This is called the weight-gaining industry. This type of industry tends to build up near market or raw material source, and are called foot-loose industry. Cotton industry is a prominent example of weight-gaining raw material.

In some industries, like the heavy chemical industry, the weight of raw materials is less than the weight of the finished product. These industries always grow up near market.

Weber's point of optimal transportation is a generalization of the Fermat point problem. In its simplest form, the Fermat problem consists in locating a point D with respect to three points A, B, and C in such a way that the sum of the distances between D and each of the three other points is minimized. As for the Weber triangle problem, it consists in locating a point D with respect to three points A, B, and C in such a way that the sum of the transportation costs between D and each of the three other points is minimized. In 1971, Luc-Normand Tellier[1] found the first direct (non iterative) numerical solution of the Fermat and Weber triangle problems. Long before Von Thünen's contributions, which go back to 1818, the Fermat point problem can be seen as the very beginning of space economy. It was formulated by the famous French mathematician Pierre de Fermat before 1640. As for the Weber triangle problem, which is a generalization of the Fermat triangle problem, it was first formulated by Thomas Simpson in 1750, and popularized by Alfred Weber in 1909.

In 1985, in a book entitled Économie spatiale: rationalité économique de l'espace habité, Tellier[2] formulated an all-new problem called the "attraction-repulsion problem", which constitutes a generalization of both the Fermat and Weber problems. In its simplest version, the attraction-repulsion problem consists in locating a point D with respect to three points A1, A2 and R in such a way that the attractive forces exerted by points A1 and A2, and the repulsive force exerted by point R cancel each other out. In the same book, Tellier solved that problem for the first time in the triangle case, and he reinterpreted spatial economics theory, especially, the theory of land rent, in the light of the concepts of attractive and repulsive forces stemming from the attraction-repulsion problem. That problem was later further analyzed by mathematicians like Chen, Hansen, Jaumard and Tuy (1992),[3] and Jalal and Krarup (2003).[4] The attraction-repulsion problem is seen by Ottaviano and Thisse (2005)[5] as a prelude to the New Economic Geography that developed in the 1990s, and earned Paul Krugman a Nobel Memorial Prize in Economic Sciences in 2008.

Labor

The labor distortion: sources of lower cost labor may justify greater transport distances and become the primary determinant in production.

Unskilled labor
industries such as the garment industry require cheap unskilled laborers to complete activities that are not mechanized. They are often termed "ubiquitous" meaning they can be found everywhere. Its pull is due to low wages, little unionization and young employees.
Skilled labor
High tech firms, such as those located in Silicon Valley, require exceptionally skilled professionals. Skilled labor is often difficult to find and is more mobile than unskilled labor.

Agglomeration and deglomeration

Agglomeration is the phenomenon of spatial clustering, or a concentration of firms in a relatively small area. The clustering and linkages allow individual firms to enjoy both internal and external economies. Auxiliary industries, specialized machines or services used only occasionally by larger firms, tend to be located in agglomeration areas, not just to lower costs but to serve the bigger populations.

Deglomeration occurs when companies and services leave because of the diseconomies of industries’ excessive concentration. Firms who can achieve economies by increasing their scale of industrial activities benefit from agglomeration. However, after reaching an optimal size, local facilities may become over-taxed, lead to an offset of initial advantages and increase in PC. Then the force of agglomeration may eventually be replaced by other forces which promote deglomeration.

Globalization

Similarly, industrial activity is considered a secondary economic activity, and is also discussed as manufacturing. Industrial activity can be broken down further to include the following activities: processing, the creation of intermediate parts, final assembly. Today with multinational corporations, the three activities listed above may occur outside MDCs.

Weber's theory can explain some of the causes for current movement, yet such discussion did not come from Weber himself. Weber found industrial activity the least expensive to produce. Least cost location then implies marketing the product at the least cost to the consumer, much like retailers attempt to obtain large market shares today. Economically, it is explained as one way to make a profit; creating the cheapest product for the consumer market leads to greater volume of sales and hence, greater profits. Therefore, companies that do not take the time to locate the cheapest inputs or the largest markets would not succeed, since their product costs more to produce and costs the consumer more.

His theory has five assumptions. His first assumption is known as the isotropic plain assumption. This means the model is operative in a single country with a uniform topography, climate, technology, economic system. His second assumption is that only one finished product is considered at a time, and the product is shipped to a single market. The third assumption is raw materials are fixed at certain locations, and the market is also a known fixed location. The fourth assumption is labor is fixed geographically but is available in unlimited quantities at any production site selected. The final assumption is that transport costs are a direct function of weight of the item and the distance shipped.

In use with his theory he created the locational triangle. His triangle is used with one market and two sources of material. This illustrated that manufacturing that utilizes pure materials will never tie the processing location to the material site. Also industries utilizing high weight loss materials will tend to be pulled toward the material source as opposed to the market. Furthermore, many industries will select an intermediate location between market and material. The last generalization is considered to be wrong because he never takes into account terminal costs and therefore is considered biased toward intermediate locations.

To further explore the location of firms Weber also created two concepts. The first is of an isotim, which is a line of equal transport cost for any product or material. The second is the isodapane which is a line of total transport costs. The isodapane is found by adding all of the isotims at a location. The reason for using isodapanes is to systematically introduce the labor component into Weber's locational theory.

Weber has received much criticism. It has been said that Weber did not effectively and realistically take into account geographic variation in market demand, which is considered a locational factor of paramount influence. Also his treatment of transport did not recognize that these costs are not proportional to distance and weight, and that intermediate locations necessitate added terminal charges. Labor is not always available in unlimited quantity at any location and is usually quite mobile through migration. Plus most manufacturing plants obtain a large number of material inputs and produce a wide range of products for many diverse markets, so his theory doesn’t easily apply. Furthermore, he underestimated the effect of agglomeration.

Works

See also

References

  1. Tellier, Luc-Normand, 1972, "The Weber Problem: Solution and Interpretation", Geographical Analysis, vol. 4, no. 3, pp. 215–233.
  2. Tellier, Luc-Normand, 1985, Économie spatiale: rationalité économique de l'espace habité, Chicoutimi, Gaëtan Morin éditeur, 280 pages.
  3. Chen, Pey-Chun, Hansen, Pierre, Jaumard, Brigitte, and Hoang Tuy, 1992, "Weber's Problem with Attraction and Repulsion," Journal of Regional Science 32, 467–486.
  4. Jalal, G., & Krarup, J. (2003). "Geometrical solution to the Fermat problem with arbitrary weights". Annals of Operations Research, 123 , 67{104.
  5. Ottaviano, Gianmarco and Jacques-François Thisse, 2005, "New Economic Geography: what about the N?", Environment and Planning A 37, 1707–1725.

Further reading

External links

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