Human Eye & RGB Colour

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This diagram is about the perception of colour. It explores how our eyes respond to wavelengths of light corresponding with red, green and blue.

  • As we look at the world on a sunny day a vast range of wavelengths of visible light enter our eyes. Each wavelength corresponds with the perception of a different spectral colour.
  • When wavelengths of light corresponding with only red, green and blue enter the eye in different proportions, our eyes are still able to see a full gamut of colours.
  • The colours we see when wavelengths corresponding with just red, green and blue light are called RGB colours.
  • Because RGB colours are produced by mixing red, green and blue light in different proportions they are not spectral colours.
  • The RGB colour model does not correspond directly with the light sensitivity of the three different types of cone cells in the human eye. Cone cells work together and cross-reference the information they receive to deduce colour.
  • RGB colours include magenta which is produced by mixing red and blue in different proportions in the absence of green.

Description

Human Eye & RGB Colour

TRY SOME QUICK QUESTIONS AND ANSWERS TO GET STARTED
Our eyes respond so well to sunlight because of its intensity and because it contains all wavelengths of visible light.
Researchers estimate the number of colours the human eye can distinguish is between one and seven million.
RGB refers to the colours red, green and blue. These are the primary colours used by the RGB colour model to mix wavelengths of light to produce a palette of as many as 16 million colours.
RGB is a colour model used to produce a full palette of colours by mixing red, green and blue light sources in different proportions.
Yes! Things appear coloured to an observer because colour corresponds with a property of light that is visible to the human eye.

About the diagram

About the diagram
  • This diagram is about the perception of colour. It explores how our eyes respond to wavelengths of light corresponding with red, green and blue.
  • As we look at the world on a sunny day a vast range of wavelengths of visible light enters our eyes. Each wavelength corresponds with the perception of a different spectral colour.
  • When wavelengths of light corresponding with only red, green and blue enter the eye in different proportions, our eyes are still able to see a full gamut of colours.
  • The colours we see when wavelengths corresponding with just red, green and blue light are called RGB colours.
  • Because RGB colours are produced by mixing red, green and blue light in different proportions they are not spectral colours.
  • The RGB colour model does not correspond directly with the light sensitivity of the three different types of cone cells in the human eye. Cone cells work together and cross-reference the information they receive to deduce colour.
  • RGB colours include magenta which is produced by mixing red and blue in different proportions in the absence of green.
Some basic facts:
  • Light is electromagnetic radiation (radiant energy), which, detached from its source, is transported by electromagnetic waves (or their quanta, photons) and propagates through space.
  • Even if humans had never evolved, electromagnetic radiation would have been emitted by stars since the formation of the first galaxies over 13 billion years ago.
  • The experience of colour is a feature of human vision that depends first of all on the construction of our eyes and then on the particular wavelength, frequency and amplitude of visible light that strikes the retina at the back of each eye at any particular moment.
  • Light enters the eye through the cornea, through the pupil and then through the lens. The lens shape is changed for near focus and controlled by the ciliary muscles.
  • Photons of light falling on the light-sensitive cells of the retina (cones and rods) are converted into electrical signals that are transmitted to the brain by the optic nerve and results in sight and vision.
Now a summary:

Things have colour because light has properties that are visible to the human eye. But what does this mean?

  • The colour of objects depends firstly on the light source and the wavelengths it emits.
  • The way any object appears to an observer depends on the material it is made from and what happens when light strikes (or is emitted from) its surface.
  • Light striking an object may undergo absorption, dispersion, reflection, refraction, scattering or transmission.
  • The appearance of an object to an observer also depends on the mental processes that lead to colour perception.
  • Spectral colours are produced by a single wavelength of light or by a band of similar wavelengths.
  • RGB colour is an additive colour model in which red, green and blue light is added together in various proportions to reproduce a wide range of other colours. The name of the model comes from the initials of the three additive primary colours – red, green, and blue.
Remember that:

When light strikes an object at least one of the following things happens:

  • Absorption. When light strikes an opaque medium the wavelengths that are not reflected are absorbed and their energy is converted to heat.
  • Dispersion. Chromatic dispersion refers to the way that light separates into its component wavelengths and the colours corresponding with each wavelength become visible.
  • Reflection. The term reflection refers to a situation where light strikes the surface of an object and some wavelengths are obstructed and bounce off. If the surface is smooth, light is reflected away at the same angle as it hits the surface. The term reflection refers then to what happens to wavelengths of light that are neither absorbed (by an opaque medium) nor transmitted (through a transparent medium).
  • Refraction. The term refraction refers to the way a light wave changes direction and speed as it travels from one medium to another.
  • Scattering. Scattering takes place when light waves are reflected in random directions at the boundary between two media. Scattering can also take place when light strikes particles or other irregularities within a medium through which light propagates.
  • Transmission. In optics, transmission refers to the passage of electromagnetic radiation through a medium.

Some key terms

  • The observer effect is a principle of physics and states that any interaction between a particle and a measuring device will inevitably change the state of the particle. This is because the act of measurement itself imposes a disturbance on the particle’s wave function, which is the mathematical description of its state.
  • The concept of observation refers to the act of engaging with an electron or other particle, achieved through measuring its position or momentum.
  • In the context of quantum mechanics, observation isn’t a passive undertaking, observation actively alters a particle’s state.
  • This means that any kind of interaction with an atom, or with one of its constituent particles, that provides insight into its state results in a change to that state. The act of observation is always intrusive and will always change the state of the object being observed.
  • It can be challenging to reconcile this with our daily experience, where we believe we can observe things without inducing any change in them.

The spectral colour model represents the range of pure colours that correspond to specific wavelengths of visible light. These colours are called spectral colours because they are not created by mixing other colours but are produced by a single wavelength of light. This model is important because it directly reflects how human vision perceives light that comes from natural sources, like sunlight, which contains a range of wavelengths.

  • The spectral colour model is typically represented as a continuous strip, with red at one end (longest wavelength) and violet at the other (shortest wavelength).
  • Wavelengths and Colour Perception: In the spectral colour model, each wavelength corresponds to a distinct colour, ranging from red (with the longest wavelength, around 700 nanometres) to violet (with the shortest wavelength, around 400 nanometres). The human eye perceives these colours as pure because they are not the result of mixing other wavelengths.
  • Pure Colours: Spectral colours are considered “pure” because they are made up of only one wavelength. This is in contrast to colours produced by mixing light (like in the RGB colour model) or pigments (in the CMY model), where a combination of wavelengths leads to different colours.
  • Applications: The spectral colour model is useful in understanding natural light phenomena like rainbows, where each visible colour represents a different part of the light spectrum. It is also applied in fields like optics to describe how the eye responds to light in a precise, measurable way.

Cone cells, or cones, are a type of neuron (nerve cell) in the retina of the human eye.

  • Cone cells are cone-shaped whilst rod cells are rod-shaped.
  • Cone cells are responsible for colour vision and function best in bright light, as opposed to rod cells, which work better in dim light.
  • Cone cells are most concentrated towards the macula and densely packed in the fovea centralis, but reduce in number towards the periphery of the retina.
  • There are believed to be around six million cone cells in the human retina.

A human observer is a person who engages in observation by watching things.

  • In the presence of visible light, an observer perceives colour because the retina at the back of the human eye is sensitive to wavelengths of light that fall within the visible part of the electromagnetic spectrum.
  • The visual experience of colour is associated with words such as red, blue, yellow, etc.
  • The retina’s response to visible light can be described in terms of wavelength, frequency and brightness.
  • Other properties of the world around us must be inferred from light patterns.
  • An observation can take many forms such as:
    • Watching an ocean sunset or the sky at night.
    • Studying a baby’s face.
    • Exploring something that can’t be seen by collecting data from an instrument or machine.
    • Experimenting in a laboratory setting.

 

RGB colour is an additive colour model in which red, green and blue light is combined to reproduce a wide range of other colours.

  • The primary colours in the RGB colour model are red, green and blue.
  • In the RGB model, different combinations and intensities of red, green, and blue light are mixed to create various colours. When these three colours are combined at full intensity, they produce white light.
  • Additive colour models are concerned with mixing light, not dyes, inks or pigments (these rely on subtractive colour models such as the RYB colour model and the CMY colour model).
  • The RGB colour model works in practice by asking three questions of any colour: how red is it (R), how green is it (G), and how blue is it (B).
  • The RGB model is popular because it can easily produce a comprehensive palette of 1530 vivid hues simply by adjusting the combination and amount of each of the three primaries it contains.

Primary colours are a set of colours from which others can be produced by mixing (pigments, dyes etc.) or overlapping (coloured lights).

  • The human eye, and so human perception, is tuned to the visible spectrum and so to spectral colours between red and violet. It is the sensitivity of the eye to the electromagnetic spectrum that results in the perception of colour.
  • A set of primary colours is a set of pigmented media or coloured lights that can be combined in varying amounts to produce a wide range of colours.
  • This process of combining colours to produce other colours is used in applications intended to cause a human observer to experience a particular range of colours when represented by electronic displays and colour printing.
  • Additive and subtractive models have been developed that predict how wavelengths of visible light, pigments and media interact.
  • RGB colour is a technology used to reproduce colour in ways that match human perception.
  • The primary colours used in a colour space such as CIELAB, NCS, Adobe RGB (1998) and sRGB are the result of an extensive investigation of the relationship between visible light and human colour vision.

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