Demographic gravitation

The following are some of the key equations (with plain English paraphrases) from his article in sociometry:

${\displaystyle F={\frac {N_{1}N_{2}}{d^{2}}}}$

(Demographic force = (population 1 multiplied by population 2) divided by (distance squared))

${\displaystyle E={\frac {N_{1}N_{2}}{d}}}$

(Demographic energy = (population 1, multiplied by population 2) divided by distance; this is also Zipf's determinant)

${\displaystyle PN_{1}={\frac {N_{2}}{d}}}$

(Demographic potential of population at point 1 = population at point 2, divided by distance)

${\displaystyle P={\frac {N}{d}}}$

(Demographic potential in general = population divided by distance, in persons per mile)

${\displaystyle {\text{gradient}}={\frac {N}{m^{2}}}}$

(Demographic gradient = persons per (i.e. divided by) square mile)

The potential of population at any point is equivalent to the measure of proximity of people at that point (this also has relevance to Georgist economic rent theory Economic rent#Land rent).

For comparison, Reilly's retail gravity equilibrium (or Balance/Break Point) is paraphrased as:

${\displaystyle {\frac {N_{1}}{d^{2}}}={\frac {N_{2}}{d^{2}}}}$

(Population 1 divided by (distance to balance, squared) = Population 2 / (distance to balance, squared))

Recently, a stochastic version has been proposed[9] according to which the probability ${\displaystyle p_{j}}$ of a site ${\displaystyle j}$ to become urban is given by

${\displaystyle p_{j}=C{\frac {\sum _{k}w_{k}d_{j,k}^{-\gamma }}{\sum _{k}d_{j,k}^{-\gamma }}}}$

where ${\displaystyle w_{k}=1}$ for urban sites and ${\displaystyle w_{k}=0}$ otherwise, ${\displaystyle d_{j,k}}$ is the distance between sites ${\displaystyle j}$ and ${\displaystyle k}$, and ${\displaystyle C}$ controls the overall growth-rate. The parameter ${\displaystyle \gamma }$ determines the degree of compactness.

• Reilly's law of retail gravitation
• Trip distribution: gravity model
• George Kingsley Zipf's demographic energy
• Central place theory
• Johann Heinrich von Thünen's spatial economics
• Walther Christaller's central place theory
• Alfred Weber's least cost location theory.
• Economic rent: Land rent.
• John Quincy Stewart, 1947. Empirical Mathematical Rules Concerning the Distribution and Equilibrium of Population, Geographical Review, Vol 37, 461–486.
• John Quincy Stewart, 1950. Potential of Population and its Relationship to Marketing. In: Theory in Marketing, R. Cox and W. Alderson (Eds) ( Richard D. Irwin, Inc., Homewood, Illinois).
• Zipf, G. K., 1946. The P1 P2/D Hypothesis: On the Intercity Movement of Persons. American Sociological Review, vol. 11, Oct
• Zipf, G. K., 1949. Human Behaviour and the Principle of Least Effort. Massachusetts