Written in
Latin, the title of the book is a word Lambert devised from (transliterated
phôs,
photos) = light, and (transliterated
metria) = measure. Lambert’s word has found its way into European languages as
photometry, '
, and '.
Photometria was the first work to accurately identify most fundamental photometric concepts, assemble them into a coherent system of photometric quantities, define these quantities with a precision sufficient for mathematical statements, and build from them a system of photometric principles. These concepts, quantities, and principles are still in use today. Lambert began with two simple axioms: light travels in a straight line in a uniform medium and rays that cross do not interact. Like
Kepler before him, he recognized that "laws" of photometry are simply consequences and follow directly from these two assumptions. In this way
Photometria demonstrated (rather than assumed) that • Illuminance varies inversely as the square of the distance from a point source of light, • Illuminance on a surface varies as the cosine of the incidence angle measured from the surface perpendicular, and • Light decays exponentially in an absorbing medium. In addition, Lambert postulated a surface that emits light (either as a source or by reflection) in a way such that the density of emitted light (
luminous intensity) varies as the cosine of the angle measured from the surface perpendicular. In the case of a reflecting surface, this form of emission is assumed to be the case, regardless of the light's incident direction. Such surfaces are now referred to as "Perfectly Diffuse" or "Lambertian". See:
Lambertian reflectance,
Lambertian emitter. Lambert demonstrated these principles in the only way available at the time: by contriving often ingenious optical arrangements that could make two immediately adjacent luminous fields appear
equally bright (something that could only be determined by visual observation) when two physical quantities that produced the two fields were
unequal by some specific amount (things that could be directly measured, such as angle or distance). In this way, Lambert quantified purely visual properties (such as
luminous power, illumination,
transparency,
reflectivity) by relating them to physical parameters (such as distance, angle, radiant power, and color). Today, this is known as "visual photometry." Lambert was among the first to accompany experimental measurements with estimates of uncertainties based on a
theory of errors and what he experimentally determined as the limits of visual assessment. Although previous workers had pronounced photometric laws 1 and 3, Lambert established the second and added the concept of
perfectly diffuse surfaces. But more importantly, as
Ernst Anding pointed out in his German translation of
Photometria, "Lambert had incomparably clearer ideas about photometry" and with them established a complete system of photometric quantities. Based on the three laws of photometry and the supposition of perfectly diffuse surfaces,
Photometria developed and demonstrated the following: :1. Just noticeable differences ::In the first section of
Photometria, Lambert established and demonstrated the laws of photometry. He did this with visual photometry and to establish the uncertainties involved, described its approximate limits by determining how small a brightness difference the
visual system could determine. :2. Reflectance and transmittance of glass and other common materials ::Using visual photometry, Lambert presented the results of many experimental determinations of specular and diffuse reflectance, as well as the transmittance of panes of glass and lenses. Among the most ingenious experiments he conducted was to determine the reflectance of the
interior surface of a pane of glass. :3. Luminous
radiative transfer between surfaces ::Assuming diffuse surfaces and the three laws of photometry, Lambert used Calculus to find the transfer of light between surfaces of various sizes, shapes, and orientations. He originated the concept of the per-unit transfer of flux between surfaces and in
Photometria showed the closed form for many double, triple, and quadruple integrals which gave the equations for many different geometric arrangements of surfaces. Today, these fundamental quantities are called
View Factors, Shape Factors, or Configuration Factors and are used in
radiative heat transfer and in
computer graphics. :4. Brightness and pupil size ::Lambert measured his own pupil diameter by viewing it in a mirror. He measured the change in diameter as he viewed a larger or smaller part of a candle flame. This is the first known attempt to quantify
pupillary light reflex. :5.
Atmospheric refraction and absorption ::Using the laws of photometry and a great deal of geometry, Lambert calculated the times and depths of twilight. :6. Astronomic photometry ::Assuming that the planets had diffusely reflective surfaces, Lambert attempted to determine the amount of their reflectance, given their relative brightness and known distance from the sun. A century later, Zöllner studied
Photometria and picked up where Lambert left off, and initiated the field of astrophysics. :7. Demonstration of additive color mixing and
colorimetry ::Lambert was the first to record the results of
additive color mixing. By simultaneous transmission and reflection from a pane of glass, he superimposed the images of two different colored patches of paper and noted the resulting additive color. :8. Daylighting calculations ::Assuming the sky was a luminous dome, Lambert calculated the
illumination by skylight through a window, and the light occluded and interreflected by walls and partitions. ==Nature of
Photometria==