Can someone explain these equations?

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In summary, equations 196 and 197 show that vector v can be written as a sum of ExB/b^2 and v', with the ExB vector being perpendicular to both E and B fields. This is possible because any two vectors can be written as a sum of another vector. This allows for easier manipulation and understanding of the equations.
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  • #2
equation 196 is just saying that v can be written as a vector sum of ExB/b^2 + v'

the ExB vector is perpendicular to both E and B fields (which in this case are perpendicular to each other)

and so subbing the expression in for v into equation 195 you get equation 197

vxB = (ExB/B^2 + v') x B = ExBxB/B^2 + v'xB = v'xB since ExBxB is zero vector.
 
  • #3
Thanks. But why is equation 196 true?
 
  • #4
If you have any two vectors p and q, you can always write p = q + v'. v' is just p-q.

The reason for doing this in Eq 196 is because the ExB vector and the v' vector each have different "nice" properties, and after you split up the equation you can work with each vector separately.
 
  • #5
Oh, ok. That makes much more sense. Thanks!
 

1. What are equations used for?

Equations are used to represent mathematical relationships between variables. They can be used to solve problems, make predictions, and describe natural phenomena in the physical world.

2. Why are equations written in a specific format?

Equations are written in a specific format to clearly show the relationship between different variables and to make it easier to solve and interpret them. The format also allows for consistency and standardization in mathematical communication.

3. What do the symbols and numbers in equations represent?

Symbols in equations represent different variables, such as quantities, measurements, or physical properties. Numbers in equations represent specific values for those variables.

4. Can equations be applied to real-life situations?

Yes, equations can be used to model and solve real-life problems. They are widely used in fields such as physics, engineering, economics, and many others to describe and understand natural phenomena and make predictions.

5. How can I understand and solve complex equations?

Understanding and solving complex equations takes practice and familiarity with mathematical concepts and operations. It can also be helpful to break down the equation into smaller parts and use known relationships and rules to solve them. Seeking help from a teacher or tutor can also be beneficial.

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