Cognitive Psychology: Colour Perception and Cognitive Processes

 

 (CP-13) Colour Perception and Cognitive Processes

Abstract: Colour perception is an essential part of cognitive psychology, helping us understand how we interpret and make sense of the visual world. This article provides an overview of color perception for BS Cognitive Psychology students. It discusses the anatomy of the eye, including the retina, photoreceptor cells, rods, and cones, which are responsible for color vision. The human eye has three types of cones that are sensitive to different ranges of wavelengths, namely the red, green, and blue cones. The article explains how the brain processes the signals from these cones to create the perception of color, and how color constancy allows our brain to perceive colors accurately despite changes in the lighting environment. Additionally, the article covers color blindness, where individuals have difficulty distinguishing between certain colors. The article also examines four theories of color vision: the Trichromatic Theory, the Opponent-Process Theory, the Retinex Theory, and the Color Center Theory. These theories offer valuable insights into how we perceive color and how the brain processes visual information.

Introduction:  Top of Form

As humans, we see the world in a spectrum of colors, but have you ever wondered how we perceive colors? The answer lies in the study of color perception. Color perception is an essential part of cognitive psychology, as it helps us understand how we interpret and make sense of the visual world. In this article, we will delve into the basics of color perception and explore its various aspects.

Color Perception:

Color perception refers to the process by which our brain interprets the colors we see through our eyes. It involves the interaction of various parts of the visual system, including the retina, optic nerve, and brain. Our perception of color is not solely determined by the wavelength of light that enters our eyes, but also by the context and environment in which we view the colors.

The Anatomy of the Eye

Before we dive into the specifics of color perception, it's important to understand the anatomy of the eye. The eye is composed of various parts, including the retina, which is the layer of tissue at the back of the eye that contains photoreceptor cells. There are two types of photoreceptor cells in the retina, namely rods and cones. Rods are responsible for vision in low-light conditions, while cones are responsible for color vision in bright light.

Color Vision and the Three Types of Cones

The human eye has three types of cones that are responsible for color vision, namely the red, green, and blue cones. Each cone type is sensitive to a particular range of wavelengths of light. The brain processes the signals from these cones to create the perception of color. For instance, when all three types of cones are stimulated equally, we perceive the color white. On the other hand, when none of the cones are stimulated, we perceive the color black.

Color Constancy

Have you ever noticed that colors appear different under different lighting conditions? For instance, a white shirt may appear yellowish under incandescent light, but appear white under natural daylight. This phenomenon is known as color constancy, which is the ability of our brain to perceive colors as being constant despite changes in the lighting environment. This is achieved through a process called color normalization, which allows our brain to adjust for variations in lighting and still perceive colors accurately.

Color Blindness

Not everyone has normal color vision. Some individuals have a color vision deficiency, also known as color blindness. This condition affects the ability to perceive certain colors, and can be caused by genetic factors or certain medical conditions. The most common form of color blindness is red-green color blindness, where individuals have difficulty distinguishing between red and green colors.

Theories of color vision:

Trichromatic Theory: This theory, proposed by Thomas Young and Hermann von Helmholtz in the 19th century, suggests that there are three types of color receptors (cones) in the retina that are responsible for color vision. These cones are sensitive to different ranges of wavelengths, with one being most sensitive to short wavelengths (blue), one to medium wavelengths (green), and one to long wavelengths (red). The brain processes the signals from these cones to create the perception of color.

Opponent-Process Theory: This theory, proposed by Ewald Hering in the 19th century, suggests that color vision is the result of three opponent processes: red-green, blue-yellow, and black-white. According to this theory, cells in the retina and brain respond to pairs of opposing colors (e.g., red vs. green), and the perception of color is based on the relative activation of these opposing processes.

Retinex Theory: This theory, proposed by Edwin Land in the 1970s, suggests that color perception is based on the interaction between the color signals from the retina and the context in which they are seen. According to this theory, the brain compares the color of an object to the colors of its surrounding environment, and adjusts the perception of color accordingly.

Color Center Theory: This theory, proposed by Lawrence Hunt in the 1950s, suggests that color perception is the result of specialized cells in the brain that respond to specific wavelengths of light. According to this theory, there are two color centers in the brain: one that responds to long wavelengths (red) and another that responds to short wavelengths (blue-green). The perception of other colors is thought to be the result of the interaction between these two color centers.

These are just a few of the many theories of color vision that have been proposed over the years. While there is still much debate about which theory is the most accurate, they all offer valuable insights into how we perceive color.

References:

1. Brainard, D. H. (1998). Color appearance and color constancy. In P. G. Grossenbacher (Ed.), Perception and the physical world: Psychological and philosophical issues in perception (pp. 63-90). John Wiley & Sons.
2. Brainard, D. H., & Wandell, B. A. (1992). Asymmetric color matching: How color appearance depends on the illuminant. Journal of the Optical Society of America A, 9(9), 1433-1448.
3. Gegenfurtner, K. R., & Kiper, D. C. (2003). Color vision. Annual Review of Neuroscience, 26(1), 181-206.
4. Gegenfurtner, K. R., & Sharpe, L. T. (1999). Color vision: From genes to perception. Cambridge University Press.
5. Goldstein, E. B. (2019). Sensation and perception. Cengage Learning.
6. Jameson, D., & Hurvich, L. M. (1989). Some quantitative aspects of an opponent-colors theory. II. Chromatic responses and spectral saturation. Vision Research, 29(5), 727-747.
7. Mollon, J. D. (1999). Color vision: A clinical perspective. Current Opinion in Neurobiology, 9(4), 431-435.
8. Nascimento, S. M. C., & Foster, D. H. (2013). Color constancy. In S. K. Shevell (Ed.), The Science of Color (2nd ed., pp. 357-386). Elsevier.
9. Palmer, S. E. (1999). Vision science: Photons to phenomenology. MIT press.
10. Regan, B. C., & Mollon, J. D. (1997). Color vision. Annual Review of Neuroscience, 20(1), 399-430.
11. Shevell, S. K. (2017). The science of color. Elsevier.
12. Werner, J. S., & Chalupa, L. M. (2016). The new visual neurosciences. MIT press.
13. Webster, M. A. (2015). Visual adaptation. Annual Review of Vision Science, 1, 547-567.
14. Witzel, C., & Gegenfurtner, K. R. (2018). Categorical perception of color: History, concepts, and methods. In A. J. Elliot (Ed.), Advances in experimental social psychology (Vol. 57, pp. 1-74). Academic Press.
15. Zeki, S. (1993). A vision of the brain. Blackwell Scientific Publications.
16. Zeki, S. (1999). Art and the brain. Journal of Consciousness Studies, 6(6-7), 76-96.
17. Zeki, S. (2015). The anatomy of illusions. Neuron, 88(4), 644-654.
18. Zhang, P., & Brainard, D. H. (2019). The relationship between color naming, unique hues, and color perception. Journal of Vision, 19(11), 11-11.

Top of Form

Top of Form

Top of Form

 

Cognitive Psychology: Information coding in visual cells

(CP-06) Information coding in visual cells

Abstract: The process of information coding in visual cells is a fundamental topic in Cognitive Psychology, providing insights into how the brain processes visual information and how we perceive the world. The process begins with sensation and vision, where sensory receptors in the eyes receive and interpret visual stimuli. The photoreceptors in the retina translate visual information into neural signals that are then sent to the brain via the optic nerve. Factors that impact information coding include illumination, spatial frequency of visual stimuli, color vision, and top-down processing. The eye plays a vital role in the process, with structures like the cornea, lens, and retina responsible for receiving and focusing light onto the photoreceptors. Understanding information coding in visual cells provides a better understanding of cognitive processes like attention, perception, and memory.

Introduction: One of the most important topics in Cognitive Psychology is information coding in visual cells. This topic is important because it helps us understand how the brain processes visual information and how we perceive the world around us. In this blog, we will discuss the process of sensation, vision, and the role of the eye in information coding.

Sensation: Sensation is the process of receiving information through the senses. The process of sensation starts with the reception of stimuli by sensory receptors. The sensory receptors are specialized cells that are located in the sense organs. For example, the eyes contain sensory receptors called photoreceptors, which are responsible for the reception of visual stimuli.

Vision: Vision is the process of interpreting visual information received by the eyes. The process of vision starts with the reception of light by the photoreceptors in the retina. The retina is the layer of tissue at the back of the eye that contains the photoreceptors. There are two types of photoreceptors: rods and cones. Rods are responsible for low-light vision, while cones are responsible for color vision.

Information coding in visual cells: The process of information coding in visual cells is the process by which the visual information is translated into neural signals that can be interpreted by the brain.

The photoreceptors in the retina are responsible for this process. When light hits the photoreceptors, it triggers a chemical reaction that causes a change in the membrane potential of the photoreceptor. This change in the membrane potential leads to the generation of an action potential, which is a neural signal that can be transmitted to the brain.

The photoreceptors are arranged in such a way that they form a pattern in the retina. This pattern is called the receptive field of the photoreceptor. The receptive field is the area of the retina that is sensitive to a particular visual stimulus. When a visual stimulus is presented in the receptive field of a photoreceptor, it triggers an action potential in that photoreceptor.

Optic nerve: The information from the photoreceptors is then transmitted to the brain via the optic nerve. The optic nerve is a bundle of nerve fibers that carries the neural signals from the retina to the brain. The neural signals are then interpreted by the brain to form a visual image.

Role of the eye: The eye plays a crucial role in the process of information coding in visual cells. The eye is responsible for the reception of visual stimuli, which is the first step in the process of vision. The eye contains several structures that are important for this process, including the cornea, the lens, and the retina.

The cornea is the transparent outer layer of the eye that helps to focus light onto the retina. The lens is a flexible structure located behind the iris that helps to further focus the light onto the retina. The retina contains the photoreceptors that are responsible for the reception of visual stimuli.

Factors affecting the process of information coding:

There are several factors that affect the process of information coding in visual cells. One of these factors is the level of illumination. Photoreceptors are more sensitive to light when the level of illumination is low. This is why we have better night vision in low light conditions.

Another factor that affects information coding in visual cells is the spatial frequency of the visual stimulus. The spatial frequency refers to the number of cycles per degree of visual angle in a visual stimulus.

·         Visual stimuli with high spatial frequency (i.e., fine details) are coded by the retina, which contains a high density of cones.

·         Visual stimuli with low spatial frequency (i.e., coarse details) are coded by the peripheral region of the retina, which contains a higher density of rods.

Color vision is also an important aspect of information coding in visual cells. Cones are responsible for color vision, and there are three types of cones that are sensitive to different wavelengths of light (i.e., red, green, and blue). The combination of these cones allows us to perceive a wide range of colors.

The process of information coding in visual cells is also influenced by top-down processing. Top-down processing refers to the use of prior knowledge and expectations to interpret sensory information. For example, if we expect to see a particular object, our brain may use this expectation to influence the interpretation of the visual information.

In conclusion, the process of information coding in visual cells is a complex and dynamic process that is influenced by several factors. By understanding this process, Cognitive Psychology students can gain a deeper understanding of how we perceive the world around us and how the brain processes visual information. Information coding in visual cells is a fascinating topic that has significant implications for our understanding of cognitive processes such as perception, attention, and memory. Through continued research in this area, we can gain a deeper understanding of how the brain processes visual information and how we perceive the world around us.

References:

1. Alilovic, J., & Brkanovic, M. (2019). Top-down processing in visual perception: An overview. International Journal of Psychophysiology, 137, 1-8. https://doi.org/10.1016/j.ijpsycho.2018.11.007
2. Baumann, O., & Mattingley, J. B. (2012). Dissociable neural circuits for encoding and retrieval of object-place associations in humans. NeuroImage, 62(1), 141-148. https://doi.org/10.1016/j.neuroimage.2012.04.050
3. De Valois, R. L., & De Valois, K. K. (1988). Spatial vision. Oxford University Press.
4. Driver, J., & Frith, C. (2000). Shifting baselines in attention research. Nature Reviews Neuroscience, 1(2), 147-148. https://doi.org/10.1038/35039084
5. Gilbert, C. D., & Li, W. (2013). Top-down influences on visual processing. Nature Reviews Neuroscience, 14(5), 350-363. https://doi.org/10.1038/nrn3476
6. Kandel, E. R., Schwartz, J. H., & Jessell, T. M. (Eds.). (2000). Principles of neural science (4th ed.). McGraw-Hill.
7. Kastner, S., & Ungerleider, L. G. (2000). Mechanisms of visual attention in the human cortex. Annual Review of Neuroscience, 23(1), 315-341. https://doi.org/10.1146/annurev.neuro.23.1.315
8. Koch, C. (1999). Biophysics of computation: Information processing in single neurons. Oxford University Press.
9. Livingstone, M. S., & Hubel, D. H. (1988). Segregation of form, color, movement, and depth: Anatomy, physiology, and perception. Science, 240(4853), 740-749. https://doi.org/10.1126/science.3283936
10. Logothetis, N. K. (1998). Single units and conscious vision. Philosophical Transactions of the Royal Society B: Biological Sciences, 353(1373), 1801-1818. https://doi.org/10.1098/rstb.1998.0336
11. Marr, D. (1982). Vision: A computational investigation into the human representation and processing of visual information. Henry Holt and Company.
12. Mishkin, M., Ungerleider, L. G., & Macko, K. A. (1983). Object vision and spatial vision: Two cortical pathways. Trends in Neurosciences, 6(10), 414-417. https://doi.org/10.1016/0166-2236(83)90190-X
13. Nieuwenhuis, S., & de Lange, F. P. (2016). The neuroscience of attention. Oxford University Press.
14. Purves, D., & Lotto, R. B. (2003). Why we see what we do: An empirical theory of vision. Sinauer Associates.