VF - Intensity Discrimination - Week 6 Flashcards
Why is intensity discrimination important?
It is fundamental to seeing, and is needed to identify the shapes of objects.
Define 4 means by which intensity discrimination is measured.
- Bipartite field - two halves of a circle with different intensities
- Superimposed bipartite field - bipartite field with a background
- Increment threshold - adjustable intensity circle with a background
- Two alternative forced choice
In terms of a threshold vs. intensity (TVI) curve, define the following and in order:
Weber’s law
Saturation
deVries-Rose law
Absolute threshold
Define the symbols for threshold and intensity
-Absolute threshold - threshold is not affected by adapting intensity
-deVries-Rose law - threshold increases as the square root of the adapting intensity
-Weber’s law - threshold increases in direct proportion to the adapting intensity
Saturation - threshold increases sharply with only small increases in adapting intensity
Threshold = ΔI
Intensity - I
What is the theoretical lower limit for intensity discrimination, and how does this apply in reality?
Are observers able to detect intensity differences if they vary by a small number of quanta?
Smallest detectable difference is theoretically one quanta.
In reality, the number of quanta in a stimulus is variable.
Impossible to always detect an intensity difference if they differ by a small number of quanta.
Define the following on a Poisson distribution:
Variance
Standard deviation
Variance = mean
Standard deviation = √mean
How do humans behave at low adapting intensities, and what law applies here?
What photoreceptor is responsible for this?
They behave as ideal detectors, and the deVries-Rose law applies.
Cone system acts as an ideal detector over this intensity range.
How do humans behave at high adapting intensities, and what law applies here?
Does the cone system perform better, the same, or worse than an ideal detector over this range?
They perform worse than an ideal detector, and Weber’s law applies here.
Cone system performs worse than an ideal detector.
Describe the formula for the deVries law, the variables included, and the log form of the equation.
Define the slope and the y intercept on the log form.
ΔI = k √I or log ΔI = 0.5 log I + log k ΔI is the threshold I is the intensity k is a constant The slope is 0.5 log k is the y intercept
Describe the formula for Webers law, the variables included, and the log form of the equation.
Define the slope and the y intercept on the log form.
ΔI = kI or log ΔI = log I + log k ΔI is the threshold I is the intensity k is a constant The slope is 1 log k is the y intercept
What does Weber’s law demonstrate about how the visual system transmits information?
It is designed to transmit information about relative luminance rather than absolute luminance.
True or false
Saturation level intensities can be accounted for by Weber’s law or the deVries-Rose law.
False, neither law holds for saturation level intensities.
True or false
The rod system cannot saturate, while the cone system does.
False
The rod system eventually saturates
The cone system will never saturate
Consider saturation. What does the cone system protect normal observers from?
What would a rod monochromat see at saturation levels?
From rod saturation.
Monochromats would see only entirely white at saturation levels, though it is not painful or due to high intensity, but only due to saturation.
What happens when you decrease test stimulus size?
Increase threshold intensity.
What happens when you decrease test stimulus duration?
Increase threshold intensity.
