There had been two strands of thought in the quest for new certainty before Newton. In his Novum Organum (1620), Francis Bacon (1561–1626) launched a skillful attack on scholasticism and urged philosophers to adopt the empirical method. The other strand was Réné Descartes’s (1596–1650) rationalist quest for certain knowledge. In Discourse upon Method (1637), Descartes started with radical doubt of everything and ended with a firm belief in the view that nature was a perfect machine governed by exact mathematical laws (Descartes’s "universal mathematics"). Thus, a new order of the universe was established and a new language had to be developed for the description of this new order. Descartes invented analytical geometry (the Cartesian coordinates) for this purpose. David Bohm observes:

This idea is depicted by Figure 1.1: in order to specify the position of a particle it is necessary to know three distances (space has three dimensions), namely (a) length, represented by the Cartesian axis X in Figure 1.1, (b) breadth, represented by Cartesian axis Y, and (c) height, represented by the Cartesian axis Z. The three distances, X, Y, and Z, are called Cartesian coordinates. The position of the particle G is expressed in the form of (X, Y, Z). The use of the Cartesian coordinates was implicit in Newtonian physics. The introduction of the Cartesian coordinates was indeed an important contribution of the Cartesian Revolution.

Another salient feature of the Cartesian Revolution, which is relevant to the subsequent development of economic analysis, was the so-called “reductionist methodology.” According to Descartes, certain knowledge should be achieved through intuition and deduction. This methodology is succinctly summarized by Fritjof Capra:

A third feature of Cartesian philosophy was the so-called “mind-matter duality.” According to Descartes, there are two independent and separate realms of nature. One of the realms is the realm of mind; he referred to this as “res cognitas.” The other realm is the realm of matter, which he called “res extensa.” This Cartesian duality led to two tenets of Western sciences: (a) the observer of the physical universe only observes but never disturbs; and (b) the physical universe is a machine governed by exact mathematical laws.

In the realm of natural sciences, the Copemican heliocentric astronomy was subsequently refined by Johann Kepler (1571–1630). Among other things, Kepler emphasized that the path of each planet is not circular as depicted by Copernicus, but rather is an ellipse with the sun slightly off center at a point known as the focus of the ellipse.

The most famous contemporary of Kepler was Galileo Galilei (1564–1642). It is interesting to note that William Shakespeare was born in the same year as Galileo and that Isaac Newton was born in the year he died. It was Galileo who finally broke the lingering bondage of Aristotelian physics and medieval scholasticism. Thus, Galileo, more than any other single person, was responsible for the birth of modern science.

Galileo’s devotion to obtain quantitative description of nature may be best illustrated by his law of falling bodies: d = 1/2gt², where d denotes the number of feet the body falls; g stands for the constant acceleration of a body dropped in a vacuum (g = 32 feet per second); and t is time in seconds. Thus, the law may be rewritten as d = 16t².

Galileo did not offer explainations for why phenomena occur, such as Heron’s famous explanation that “nature abhors a vacuum.” His formula is precise and quantitatively complete in a way that is characteristic of modern science.

It may be said that it was Galileo who planted the seed of what John Hicks called the “New Causality”:

Frangois Quesnay’s tableau economique (1758), the quantity theory of money elucidated by John Locke (1632–1704), David Hume (1711–76), and Richard Cantillon (1680–1734), as well as David Ricardo’s one-sector “corn model” (1815) brought forth during the so-called “corn laws controversy” were all in line with the “New Causality.” Even today economists are still attempting to fit observed events into some mathematical models.