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| − | * | + | * In the section on controlling k-subspaces, we have the following equations: <br/> |
| + | <math>\begin{align} | ||
| + | L_x\frac{di(t)}{dt} &= v_x(t) \quad G_x(t) = M_xi(t) \\ | ||
| + | L_y\frac{di(t)}{dt} &= v_y(t) \quad G_y(t) = M_yi(t) | ||
| + | \end{align}</math><br/> | ||
| + | where <math>v_x(t)</math> and <math>v_x(t)</math> are the voltage across the respective coils and <math>L_x</math> and <math>L_y</math> are their respective inductances. | ||
| + | |||
| + | Is <math>i</math> the same for both the coils? | ||
Latest revision as of 08:00, 28 June 2013
- ↳ Topic 3: Magnetic Resonance Imaging
- ↳ Talk: Magnetic Resonance Imaging
The Bouman Lectures on Image Processing
A sLecture by Maliha Hossain
This is the talk page for the sLecture notes on the Magnetic Resonance Imaging. Please leave me a comment below if you have any questions, if you notice any errors or if you would like to discuss a topic further.
Questions and Comments
- In the section on controlling k-subspaces, we have the following equations:
$ \begin{align} L_x\frac{di(t)}{dt} &= v_x(t) \quad G_x(t) = M_xi(t) \\ L_y\frac{di(t)}{dt} &= v_y(t) \quad G_y(t) = M_yi(t) \end{align} $
where $ v_x(t) $ and $ v_x(t) $ are the voltage across the respective coils and $ L_x $ and $ L_y $ are their respective inductances.
Is $ i $ the same for both the coils?
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