This is the conceptual overview for Tangram's lighting system. For technical reference, see the Lights page.
A Tangram map is a 3D scene, containing 3D objects constructed from your map data. The colors of those objects are taken from the color declarations in your scene file, but the way those colors appear may be modified by lights. (If no lights are defined, the colors will be displayed on the map with no modifications.)
Tangram uses a common computer graphics lighting system, in which light from light sources interacts with materials defined on objects. We have implemented a number of light types including point lights, directional lights, and ambient lights.
First, a bit about light components.
Tangram's lighting model is based on the Blinn-Phong shading model used in OpenGL 2.0, which involves three light components: diffuse, specular, and ambient. (These are sometimes called terms, as they are literally separate terms in the lighting equation.)
Diffuse: this is light that comes from a light source, hits a surface, and scatters in all directions. This is what is usually understood as the visible color.
Specular: these are light rays that bounce from a surface directly to our eyes, producing a distinctive bright area very common on glossy, metallic, or glass surfaces.
Ambient: this is light that comes from all directions. Imagine this property as the light that bounces around in a room. Thinking of it another way, if you are outside in a sunny day, even in the shade you can perceive colors, because the sun rays reflect off of surfaces and bounce around. Ambient light is often used as a "fill" color, to brighten shadows.
The way lights affect the appearance of an object also depends on the object's material.
A material can define diffuse, specular, and ambient properties, which determine how much the material will reflect each kind of light.
So in order to get high specular we need a material with high specular values too; ambient light will only reflect from a material with an ambient property, and diffuse light bounces off of a diffuse material.
For more, see our Materials Overview.
Physics class refresher: In the RGB additive color model, all colors can be made through some combination of red, green and blue.
Colored light illuminates objects of the same color. Red light only illuminates colors with red in them, and won't illuminate colors without any red included – the same goes for green and blue.
In this model, the color white is the combination of pure red, green, and blue – so white light can illuminate objects of any color.
(Black light only illuminates ravers, and is not included in the Blinn-Phong shading model.)
Object materials define the colors of objects, per shading component. So, a red diffuse light will illuminate a red diffuse color. And because white includes the color red, white diffuse light will illuminate a red diffuse material; likewise, a red diffuse light shining on a white diffuse surface produces the same effect. You can think of lights and materials as emitters and receptors.
In the Blinn-Phong model, the separate light components are also additive. Importantly, a single material can define all three properties, and they can all interact together.
Example: colored light components
Let's analyze the following example of a pure white material lit with green diffuse, blue specular, and red ambient light:
material: ambient: white diffuse: white specular: white lights: light1: type: point position: [1,1,2.4] ambient: [.5,0,0] diffuse: [0,1,0] specular: [0,0,1]
Note that we're using a single point light which emits all three light components.
Tangram currently defines four light types: directional, ambient, point, and spotlight. Except for the ambient light, they can all emit all three lighting components, and are often useful in combination.
This light casts rays in a single direction, as though it were an infinite distance away. It can be thought of as a "sun" light, and is one of the most useful lights for 3D top-down maps. Most of Tangram's demo maps use a directional light as the primary light source.
lights: light1: type: directional direction: [0, 1, -.5] diffuse: 1 ambient: .3
This light casts a global ambient light into the scene.
Because ambient lights cast light equally from every direction, they tend to flatten the appearance of 3D geometry. You can think of them as a "flat" light, and are useful for 2D maps, and for situations where color fidelity is important.
lights: light1: type: ambient ambient: 1
Point lights act like a light bulb in a scene, casting rays in all directions from a central point, which is positioned in conjunction with the
Origin can be specified as relative to three different spaces: world, camera, and ground: (try each demo to see the difference):
- In world space, the light position is relative to a point on the map:
lights: light1: type: point position: [-74.0170, 40.7031, 100] origin: world ambient: .3 diffuse: 1. specular: .2
- In camera space, the position is relative to the camera:
lights: light1: type: point position: [0, 0, -1800] origin: camera ambient: .3 diffuse: 1. specular: .2
- In ground space, the position is relative to the point on the ground in the center of the current view:
lights: light1: type: point position: [0, 0, 100px] origin: ground ambient: .3 diffuse: 1. specular: .2
Other light parameters
Optionally, you can limit the effect of a point light or spotlight with the radius and attenuation parameters. By default, lights have no set radius or attenuation.
A light radius defines the limit of the light's effect. It can be specified in one of two ways:
- A single value sets an outer radius:
lights: light1: type: point position: [-74.0170, 40.7031, 100] radius: 500 ambient: .3 diffuse: 1. specular: .2
- A pair of values sets an inner and outer radius. The inner radius defines an area of constant illumunation, without any attenuation.
lights: light1: type: point position: [-74.0170, 40.7031, 100] radius: [500, 700] ambient: .3 diffuse: 1. specular: .2
The attenuation of a light defines the way a light's intensity decreases as the outer radius is approached. The attenuation value is the exponent factor of the falloff function: a value of
0 = no falloff,
1 = a linear curve,
2 = a quadratic curve, etc. In general, higher values result in sharper light edges.
- If no radius is defined, the attenuation curve goes to infinity:
lights: light1: type: point position: [-74.0170, 40.7031, 100] attenuation: 0.1 ambient: .3 diffuse: 1. specular: .2
- With a single radius value, the attenuation curve operates between the position of the light to the outer radius.
lights: light1: type: point position: [-74.0170, 40.7031, 100] radius: 700 attenuation: 2.0 ambient: .3 diffuse: 1. specular: .2
- With a pair of inner/outer radius values, the attenuation curve will operate between the inner and the outer radius.
lights: light1: type: point position: [-74.0170, 40.7031, 100] radius: [500,700] attenuation: 2.0 ambient: .3 diffuse: 1. specular: .2
Spotlights describe a cone of light. They have a
direction like a directional light, and can have
attenuation values like a point light, but they also have two unique properties:
angledefines the width of the spotlight's beam, in degrees. By default this is
attenuation, but from the center of the beam to the sides. By default this is
lights: light1: type: spotlight position: [-74.0170, 40.7031, 100] direction: [1, 1, 0] exponent: 30. ambient: .3 diffuse: 1 specular: .2