Vector A - Vector B: Magnitude Calculation

In summary, the conversation discusses the calculation of vector magnitudes and angles using the method of components. It is advised to draw a diagram to visualize the vectors and use the pythagorean theorem to find the magnitude. However, this method may not work for subtracting two vectors, as they are not necessarily perpendicular. Other approaches, such as reversing the direction of one vector or finding the diagonal of a parallelogram, can be used to find the magnitude and direction of the resulting vector.
  • #1
AraProdieur
27
0

Homework Statement


Vector A has a magnitude of 11 and points in the positive x-direction. Vector B has a magnitude of 22 and makes an angle of 32 degrees with the positive x-axis.
What is the magnitude of Vector A minus Vector B?

Homework Equations


The Attempt at a Solution

 
Physics news on Phys.org
  • #2
Can you describe where you're getting stuck and what you tried?
 
  • #3
Another question.

I also have another question whereas it states: Use the method of components to find the magnitude and direction of the vector sum R1 where R1= A + B. The Vector A= 15.2 m at an angle alpha= 180 degrees from the positive horizontal axis, and Vector B = 17.2 m at an angle Beta= 41.3 degrees from the positive horizontal axis. Answer in meters. Answer in units of m.

What is the angle, theta 1, from the positive horizontal axis of the vector sum, R 1?

What is the magnitude of the vector difference R 2 where R 2= Vector A - Vector B?

What is the angle, theta 2, of the resulting vector?

What is the magnitude of the vector difference R 3 where R 3= B - A?

What is the angle, theta 3, of the resulting vector?
 
Last edited:
  • #4
learningphysics said:
Can you describe where you're getting stuck and what you tried?
I've only sketched it to get a graphical representation of the vectors, but other than that I have only gotten the resultant magnitude of A + B, but don't know how to get the resultant magnitude for A - B.
 
  • #5
draw a llgm with two vectors A and B,
you have found one diagonal, just find other one, and it would be A - B

or,
reverse the direction of vector B
 
  • #6
AraProdieur said:
I've only sketched it to get a graphical representation of the vectors, but other than that I have only gotten the resultant magnitude of A + B, but don't know how to get the resultant magnitude for A - B.

A - B is the resultant of A and (-B). Use the same approach as before except use -B instead of B...

another idea... draw both vectors originating from the same point... what is the vector joining the arrow ends of B and A?
 
  • #7
rootX said:
draw a llgm with two vectors A and B,
you have found one diagonal, just find other one, and it would be A - B

or,
reverse the direction of vector B


Yes, I know what you are referring to about the -B pertaining to its opposite direction, but the problem is I only know how to find the resultant magnitude for A + B and don't know how to find it for A - B because it's different since it's only two vectors and not more.
 
  • #8
learningphysics said:
A - B is the resultant of A and (-B). Use the same approach as before except use -B instead of B...

another idea... draw both vectors originating from the same point... what is the vector joining the arrow ends of B and A?

Ok, so but isn't finding the magnitude of the resultant vector using basically the pythagorean theorem? If I use -B it will come out to the same answer. The thing that I'm confused about is that when I draw it graphically the A + B resultant vector looks shorter than the A - B resultant vector. So the problem is that I don't know how to find that A - B resultant vector, I only know the A + B resultant vector.
 
  • #9
AraProdieur said:
Yes, I know what you are referring to about the -B pertaining to its opposite direction, but the problem is I only know how to find the resultant magnitude for A + B and don't know how to find it for A - B because it's different since it's only two vectors and not more.

So you have drawn A - B, but are just having trouble calculating the magnitude?
 
  • #10
AraProdieur said:
Ok, so but isn't finding the magnitude of the resultant vector using basically the pythagorean theorem? If I use -B it will come out to the same answer. The thing that I'm confused about is that when I draw it graphically the A + B resultant vector looks shorter than the A - B resultant vector. So the problem is that I don't know how to find that A - B resultant vector, I only know the A + B resultant vector.

No, the pythagorean theorem is only for right triangles... this isn't a right triangle... pythagorean theorem won't work for A-B or A + B.
 
  • #11
learningphysics said:
So you have drawn A - B, but are just having trouble calculating the magnitude?

Yes, the way I depicted it was with Vector A going towards the right with a magnitude of 11 along the x-axis, while the -B is at 212 degrees going in the southwest direction with a magnitude of 22.
 
  • #12
learningphysics said:
No, the pythagorean theorem is only for right triangles... this isn't a right triangle... pythagorean theorem won't work for A-B or A + B.

? But I've used it before to determine the magnitude value of three vectors with their x and y coordinates provided.
 
  • #13
AraProdieur said:
? But I've used it before to determine the magnitude value of three vectors with their x and y coordinates provided.

Yes... from the x and y components, you can calculate the magnitude using the pythagorean theorem... That is because the x component is a vector in the x direction... the y component is a vector in the y direction... they are perpendicular and represent a right triangle...

if you calculate the x component (call it x) and y component (call it y) of A+B... then you can use the pythagorean theorem to calculate the magnitude... so maginitude = [tex]\sqrt{x^2 + y^2}[/tex] but this is not equal to [tex]\sqrt{A^2 + B^2}[/tex]

ie: A and B are not the x and y components of A+B...
 
  • #14
learningphysics said:
Yes... from the x and y components, you can calculate the magnitude using the pythagorean theorem... That is because the x component is a vector in the x direction... the y component is a vector in the y direction... they are perpendicular and represent a right triangle...

if you calculate the x component (call it x) and y component (call it y) of A+B... then you can use the pythagorean theorem to calculate the magnitude... so maginitude = [tex]\sqrt{x^2 + y^2}[/tex] but this is not equal to [tex]\sqrt{A^2 + B^2}[/tex]

Oh, I see, so then how do I find the resultant magnitude of A - B?
 
  • #15
Have you studied the law of cosines and the law of sines for triangles (non-right triangles)?

EDIT: You can also calculate the x-component of A-B, and the y-component of A-B... then use pythogrean theorem.

Both approaches are good... it's up to you...
 
Last edited:
  • #16
learningphysics said:
Have you studied the law of cosines and the law of sines for triangles?

Yes, but I'm not very familiar with using it with the vectors.
 
  • #17
learningphysics said:
Have you studied the law of cosines and the law of sines for triangles (non-right triangles)?

EDIT: You can also calculate the x-component of A-B, and the y-component of A-B... then use pythogrean theorem.

Both approaches are good... it's up to you...

So the x/y component of Vector A would be <11,0>? and the vector component to find -B would be cos(212)= x/22? By which I would then use tan to find the y-component value?
 
Last edited:
  • #18
AraProdieur said:
Yes, but I'm not very familiar with using it with the vectors.

Once you see the triangle you need... just approach it like triangles now... at this point don't think about them being vectors...

you've got the triangle made up of |A|, |-B|, and |A-B|... You already know |A|, |-B| and the angle between these two...

So you've got a triangle where you know two sides, and the angle between the two sides... you want the third side... do you see how to use the cosine rule here to calculate the third side?
 
  • #19
AraProdieur said:
So the x/y component of Vector A would be <11,0>? and the vector component to find -B would be cos(212)= x/22? By which I would then use inverse tan to find the y-component value?

No you'd use sin to calculate the y component... so once you get the x and y components of -B... just add A and -B... then get the magnitude of that vector using pythagorean theorem...

I highly recommend using the other approach also for the purpose of learning... you should know how to do it both ways.
 
Last edited:
  • #20
learningphysics said:
Once you see the triangle you need... just approach it like triangles now... at this point don't think about them being vectors...

you've got the triangle made up of |A|, |-B|, and |A-B|... You already know |A|, |-B| and the angle between these two...

So you've got a triangle where you know two sides, and the angle between the two sides... you want the third side... do you see how to use the cosine rule here to calculate the third side?

Ok, so far pertaining to my -B vector I received as the x-component -18.6571 and the y-component as -11.6582. Is this correct? and to my A vector, x-component is just 11 and y-component is zero?
 
  • #21
Yes, that looks correct. add the two vectors...
 
  • #22
learningphysics said:
Yes, that looks correct. add the two vectors...

Final Answer for magnitude resultant of A - B is 13.94795?
 
  • #23
AraProdieur said:
Final Answer for magnitude resultant of A - B is 13.94795?

Yes, that's correct. Now with the other approach:

You've got the triangle composed of A, -B, and A-B...

This is a triangle with sides, 11, 22 and an angle of 32degrees between them... using the cosine rule I can directly calculate the third side which is the magnitude of A-B:

r^2 = 11^2 + 22^2 - 2(11)(22)cos(32)
r^2 = 194.54
r=13.9479

I personally prefer this method...
 
  • #24
learningphysics said:
Yes, that's correct. Now with the other approach:

You've got the triangle composed of A, -B, and A-B...

This is a triangle with sides, 11, 22 and an angle of 32degrees between them... using the cosine rule I can directly calculate the third side which is the magnitude of A-B:

r^2 = 11^2 + 22^2 - 2(11)(22)cos(32)
r^2 = 194.54
r=13.9479

I personally prefer this method...

Thank you so much for your help. I really appreciate it and I was wondering if you could help me out on one more problem?

If so, the problem is Four vectors, each of magnitude 62 m, lie along the sides of a parallelogram as shown in the figure. The angle between vector A and B is 49 degrees.
What is the magnitude of the vector sum of the four vectors? Answer in units of m.

So far, I have drawn the picture and made out with a parallelogram with the left side as vector A, the top vector C, the right vector D, and the bottom vector B with all of the sides congruent to each other respective to 62 m, and also the angle with between vector A and B is 49 degrees which also means that between C and D is the same while between both A and C and B and D is 131 degrees in between.

What I've been thinking was since I have to find the magnitude of the vector sum of the four vectors, wouldn't it be the same as finding the magnitude diagonal of the parallelogram? or am I off the tee here?
 
  • #25
Hmmm... so the way I understand the problem, the vector A = the vector D... and the vector B = the vector C ? Remember that a vector is determined by its magnitude and direction... so if two vectors are parallel (ie they have the same direction), and they have the same magnitude, then they are equal vectors,,,

So A+B+C+D = 2A + 2B = 2(A+B) ?

So just calculate the resultant A+B, and then 2(A+B)... is in the same direction but with double the magnitude...

Hope I'm understanding the problem correctly.
 

What is the formula for calculating the magnitude of Vector A - Vector B?

The formula for calculating the magnitude of Vector A - Vector B is √(Ax - Bx)^2 + (Ay - By)^2 + (Az - Bz)^2, where Ax, Ay, and Az are the components of Vector A and Bx, By, and Bz are the components of Vector B.

What does the magnitude of Vector A - Vector B represent?

The magnitude of Vector A - Vector B represents the length or size of the resulting vector when Vector B is subtracted from Vector A.

How is the magnitude of Vector A - Vector B affected by the direction of the two vectors?

The magnitude of Vector A - Vector B is affected by the direction of the two vectors, as it takes into account the difference in their components. If the two vectors are pointing in opposite directions, the magnitude will be larger. If they are pointing in the same direction, the magnitude will be smaller.

Can the magnitude of Vector A - Vector B be negative?

Yes, the magnitude of Vector A - Vector B can be negative. This can occur if Vector B is longer than Vector A, resulting in a negative value for the magnitude.

What is the unit of measurement for the magnitude of Vector A - Vector B?

The unit of measurement for the magnitude of Vector A - Vector B is the same as the unit of measurement for the individual vectors, such as meters (m) or newtons (N).

Similar threads

  • Introductory Physics Homework Help
Replies
16
Views
669
  • Introductory Physics Homework Help
Replies
14
Views
230
  • Introductory Physics Homework Help
Replies
2
Views
691
  • Introductory Physics Homework Help
Replies
4
Views
151
  • Introductory Physics Homework Help
2
Replies
44
Views
2K
  • Introductory Physics Homework Help
Replies
6
Views
1K
  • Introductory Physics Homework Help
Replies
25
Views
1K
  • Introductory Physics Homework Help
Replies
2
Views
532
  • Introductory Physics Homework Help
Replies
6
Views
2K
  • Introductory Physics Homework Help
Replies
5
Views
3K
Back
Top