Understanding Right and Left Handed Systems in Vector Calculus

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In vector calculus, a right-handed system is defined as one where the orientation is positive, while a left-handed system is negative. The discussion confirms that if vectors a, b, and c form a right-handed system, then permutations like b, c, a and c, a, b also maintain this orientation. However, arrangements such as a, c, b and c, b, a are classified as left-handed due to only one switch in their positions. To validate these classifications, one can refer to the determinant of the vectors; a positive determinant indicates a right-handed system, while a negative determinant signifies a left-handed system. Understanding these definitions and properties is crucial for proving the orientation of vector arrangements.
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If a, b, c are right handed system, then so are b, c, a, and c, a, b. In this case, the vectors a, c, b and c, b, a and b, a, c are a left handed system.

In order to prove the above statement, I know that the right handed system is positive and the left handed system is negative. So for the second part, b,c,a and c, a, b are right handed because the positions were switched two times, so that makes a right handed system. But, a, c, b and c, b, a and b, a, c are only switched once, so that makes a left handed system. Is this how I prove this statement?
 
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first you need a definition of right handed and left handed. what is it? or of orientation - preserving. then just check that these cases obey the definition.
 
This is not a formal definition but, when the determinant is negative, it's left handed and if it's positive, it's right handed.
 
Thread 'How to define a vector field?'

Thread 'How to define a vector field?'

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