Dynamic Causal Modelling - Units of Parameters[edit | edit source]

In general, the coupling parameters in DCM (matrices A,B,C) are in units of hertz. They are rate constants, defining the rates of change within or between regions. Certain parameters, however, are log scaling parameters - this refers to a transformation used to force these parameters to take positive or negative values.

The notion of rate constants is most easily illustrated for the self-connections - the diagonal entries of the A matrix.

Self-connections[edit | edit source]

Imagine a one region DCM with a single inhibitory self-connection (i.e. a single value in matrix A). The level of activity in this region (its state) is denoted ${\displaystyle z}$. This system can be modelled as a first-order linear differential equation:

${\displaystyle {\begin{aligned}{\dfrac {dz}{dt}}&=az\\z(t)&=z_{0}\cdot e^{-at}\\\end{aligned}}}$

The parameter ${\displaystyle a}$ controls the rate of decay in the region. To see why, we can consider the half-life of the system.

Relationship with half-life[edit | edit source]

The half-life ${\displaystyle \tau }$ is the time at which activity in our example region has fallen to half its starting level. From the definition above, we know that we can calculate the activity at time ${\displaystyle \tau }$:

${\displaystyle {\begin{aligned}z(\tau )&=0.5z_{0}\\&=z_{0}\cdot e^{-a\tau }\end{aligned}}}$

We can re-arrange this expression to find the value of ${\displaystyle \tau }$ and ${\displaystyle a}$:

${\displaystyle {\begin{aligned}e^{-a\tau }&={\dfrac {0.5z_{0}}{z_{0}}}\\&=0.5\\\\-a\tau &=ln(0.5)\\&=ln(1)-ln(2)\\&=0-ln(2)\\&=-ln(2)\\\\\tau &={\dfrac {-ln(2)}{-a}}\\&={\dfrac {ln(2)}{a}}\\\\a&={\dfrac {ln(2)}{\tau }}\end{aligned}}}$

Thus, ${\displaystyle a}$ is inversely proportional to the half-life ${\displaystyle \tau }$. The more negative the value of ${\displaystyle -a}$, the quicker activity decays in this region.

Constraining the sign[edit | edit source]

Sometimes we need to force the sign of a coupling parameter to be positive or negative. For instance, we constrain the self-connection on each region, ${\displaystyle -A}$, to be negative - ensuring that it decays and the system reaches stability. Another example is two-state DCM, which explicitly represents particular connections as being excitatory or inhibitory. Typically, the approach taken is to treat the parameters as being the logarithm of the coupling strength, rather than the coupling strength itself. Then within the code of the model, its value is exponentiated prior to use, and can be made positive:

a = exp(A);

or negative:

a = -exp(A);

It is important when interpreting the results, therefore, to know which parameters are simple coupling strengths and which are log parameters. This depends on which DCM model you use, and these are laid out below.

Specific Models[edit | edit source]

One-state DCM for fMRI[edit | edit source]

This is the standard or 'vanilla' DCM for fMRI. All connections in the A,B,C and D matrices are coupling parameters in units of Hz, with the exception of the self-connections on the A-matrix, which are log scaling parameters. The intention here is two-fold - to force these to always be negative, and to set a default strength of -0.5Hz when the value in the A-matrix is zero.

To achieve this, the values for the self-connections in the A-matrix go through the following transformation within the model:

Where ${\displaystyle A}$ is the value that appears in the A-matrix and ${\displaystyle a}$ is the value used in the model.

Two-state DCM for fMRI[edit | edit source]

In this model, all values in the A and B (but not C) matrix are log scaling parameters.