Yes.
No. The largest possible resultant magnitude is the sum of the individual magnitudes.The smallest possible resultant magnitude is the difference of the individual magnitudes.
Two vectors: no. Three vectors: yes.
Two vectors, no; three vectors yes.
It is not possible. The maximum magnitude is obtained when the vectors are aligned and in this case the resultant has a magnitude which is the sum of the individual vectors. In the given example, the maximum possible magnitude for the resultant is 16 units. In general |a+b| <= |a| + |b| where a, b are vectors and |a| is the magnitude of a
Yes, put the three vectors in a plane, with a separation of 120 degrees between each vector and each of the other vectors.
No. The largest possible resultant magnitude is the sum of the individual magnitudes.The smallest possible resultant magnitude is the difference of the individual magnitudes.
Two vectors: no. Three vectors: yes.
Two vectors, no; three vectors yes.
Two vectors: no. Three vectors: yes.
mAYBE
No.
It is not possible. The maximum magnitude is obtained when the vectors are aligned and in this case the resultant has a magnitude which is the sum of the individual vectors. In the given example, the maximum possible magnitude for the resultant is 16 units. In general |a+b| <= |a| + |b| where a, b are vectors and |a| is the magnitude of a
Let two equal magnitude vectors be 'X'.. Then, resultant=1.414X
Yes, put the three vectors in a plane, with a separation of 120 degrees between each vector and each of the other vectors.
If their sum (resultant) is 0, then the magnitude of the resultant must be 0.
By all means. Using Newton's third law (f=ma) Multiply the vectors by 0 and you're home
yes