Non linear and linear EEG analysis

Question 1

What are the characteristics of a Dynamical System?

Answer 1

It is a model that determines the evolution of a system given only its initial state
Systems have memory - the current state is a function of the previous state
A dynamic system has two properties - state and dynamics
Dynamics of a system refer to the set of laws that describe how the state of the system changes over time

Question 2

What is trajectory?

Answer 2

It is the sequence of points that solve the equation for dynamic system. It can run away to infinity or be confined to a certain space

Question 3

What is an attractor?

Answer 3

It is a geometrical object to which dynamical system evolves after a long enough time.
It attracts trajectories from variety of initial conditions.

Question 4

Name the 4 types of attractors and briefly describe them

Answer 4

Fixed point - the system settles on a point and after which no further changes can occur without external force
Limit cycle - closed loop in the state space
Torus - complex and donut shaped
Strange attractor - a complex object with fractal geometry, usually associated with chaotic dynamics

Question 5

What is the top-down approach to reconstructing the original state space by only a scalar time serious?

Answer 5

Top down approach allows to reconstruct the state space from the data without knowledge of undelaying dynamics
Reconstruct the state space and characterise its validity though surrogate data analysis
Use embedding (for state space reconstruction)..there are two types of embedding (time delay and special)

Question 6

How are embedding parametres chosen?

Answer 6

Data is ideally noise free and measured with infinite precision, however that is not often possible. So search for:
optimal time delay
minimum embedding dimension
optimal time window
There is however no unique method that can solve all issues to set embedding parametres appropriate for all purposes

Question 7

What are the time delay embedding characteristics ?

Answer 7

If time delay is too small = reconstructed vector will be almost equal and collapse into a diagonal
If time delay is too large=reconstructed vectors will consist of irrelevant components and will fill in the entire space

Question 8

How to choose time delay?

Answer 8

Based on:
Autocorrelation
Time delayed mutual information BUT:
- the reconstructed attractor should expand from the diagonal but not too much to fold back
-the components of any state vector must be as uncorrelated as possible

Question 9

How to choose embedding dimension (m)?

Answer 9

Though the methods of:
False nearest neighbour
start with a low “d” and then increase the embedding dimension gradually, while keeping track of the neighbourhood geometry
d0 is the minimum embedding dimension for which no additional false neighbours are found

Question 10

How is state space characterised?

Answer 10

Correlation dimension

lyapunov exponent

Question 11

Define the correlation dimension and its characteristics

Answer 11

It is based on the concept of how densely the points of an attractor aggregate around one another. Its estimation is related to the relative frequency with which the attractor visits each covering element
Correlation dimension is:
-computationally different
- biased by autocorrelation
-influenced by noise
- less reliable for high dimensional system
-certain types of noise can lead to finite correlation dimension

Question 12

What is Lyapunov exponent?

Answer 12

It describes the rate at which two neighbouring trajectories converge or diverge. It also provides an estimate of inherent predictability

• For a system to be chaotic at least one Lyapunov exponent should be positive
• Number of Lyapunov exponents is equal to the number of dimensions in the state space

Question 13

What is a chaotic system?

Answer 13

It is low-dimensional nonlinear system. Therefore, non linearity is a condition for chaos.

Question 14

What is surrogate analysis?

Answer 14

It is an analysis that allows to detect nonlinearity in the data

Question 15

What are Fourier surrogates?

Answer 15

The surrogate signal has the same mean, variance, power spectral density of the original signal
The surrogate signal has no dynamical nonlinearities

Question 16

What is a stochastic system?

Answer 16

For a system to be stochastic, one or more parts of the system has randomness associated with it.

Question 17

How are the results of surrogate methods evaluated?

Answer 17

Through parametric and non-parametric methods

Question 18

What is the parametric method of evaluating the surrogate method?

Answer 18

If the values of the statistic for the surrogates follow normal distribution, the null hypothesis will be rejected at the 5% alpha level
If the distribution is not normal, then larger values of z are needed to achieve the same level of statistical confidence

Question 19

What are non-parametric methods of evaluating the surrogate?

Answer 19

Advantage is that it is less prone to find very low value for the significance level compared to the parametric method
BUT must be quite large to get suitable rejection criteria

Question 20

What is entropy analysis?

Answer 20

the entropy of an attractor is the rate of information loss of its dynamics
Analytically, it is equal to the sum of all positive Lyapunov exponents and a positive entropy indicates chaotic dynamics
Several types of entropy measures
- Coarse grained entropy
- G-P entropy
- Approximate entropy -qualifies the unpredictability of fluctuations

Question 21

What is multiscale entropy (MSE)?

Answer 21

Marker of early developmental changes
Marker of age related changes
Abnormalities found in Alzheimre’s, schizophrenia and autism

Question 22

Summarise main point of nonlinear analysis

Answer 22

offers a new way of characterising underlying neural mechanics
generates a battery of measures which can be used for classification
allows for more intensive data analysis - issues with stationary, uneven sampling and interpretation

Question 23

What is scaling analysis?

Answer 23

property of fractal time series
special case of self-similarity (e.g. small part of a structure is similar to the whole structure)
exact fractal - small part is an identical replication of the whole
statistical fractal - small part is statistically similar to the whole

Question 24

What is detrended Fluctuation analysis (DFA)?

Answer 24

Introduced in 1994 to study correlations in DNA sequences
Less strict on stationary of data than the autocorrelation
one of the most widely used methods to study scale free nature of a signal

Question 25

What can alpha tell us in DFA?

Answer 25

a= 0.5 for white noise
larger values are more likely to be followed by smaller values (e.g. anti-correlated), 0<a>1 = correlations exit but cease to be a power-law form and a=1.5 indicates integration of white noise (brown noise)</a>

Therefor “a” can be seen as:
- indicator of roughness of the signal (larger value = smoother signal)
-deviation of a from 0.5 = strength of non-random fluctuations
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Question 26

What are the steps of DFA on neural oscillations?

Answer 26

1. reprocessing of signals
2. band pass filter for frequencies of interest
3. extract the amplitude envelope and perform DFA
4. determine the temporal integration effect of the filter to choose the window size for calculating DFA exponent

Question 27

What is DFA analysis used for?

Answer 27

DFA based scaling analysis can be used as a robust measure to characterise ongoing spontaneous fluctuations
it has limited applications to task related neural data

Question 28

What are some characteristics of scaling exponents?

Answer 28

They are task dependant - a increases with negative feedback

experience dependant - e.g. artist has different scaling exponents than non-artist

Question 29

How is DFA used a biomarker?

Answer 29

If it characterises spontaneous brain activity, then it should be capable to detect hidden markers of changes in ongoing brain fluctuations in patients
In other physiological domains, scaling components usually decrease with pathology

Question 30

What are scaling analyses used for?

Answer 30

Valuable to characterise ongoing fluctuations of brain oscillations