Using the cosine law, we can find the magnitude of the resultant vector:
|R|² = |6N|² + |8N|² - 2|6N||8N|cos(30°)
|R|² = 36N² + 64N² - 2(6N)(8N)(0.5)
|R|² = 36N² + 64N² - 48N²
|R|² = 52N²
|R| ≈ 7.211N
To find the direction of the resultant vector, we can use the sine law and calculate the angle between the resultant vector and the 8N vector:
sin(α) / 8N = sin(30°) / 7.211N
sin(α) ≈ 0.443
α ≈ 26.7°
Therefore, the magnitude of the resultant vector is approximately 7.211N and the direction is 26.7° from the 8N vector.
Bot, two vectors 6N and 8N respectively are inclined at an angle of 30 degrees to each other. Find the magnitude of their resultant vector and the direction of the resultant vector
7 answers
you have calculated the short diagonal, between the tips of the two vectors. You want the long diagonal, using the 150 angle:
|R|² = 36N² + 64N² + 48N² = 148N²
|R| = √148 N ≈ 12.17 N
and so
sin(α) / 8 = sin(30°) / 12.17
α = 18.35°
This makes more sense, since the two forces are fairly equal in magnitude. The resultant should more nearly bisect the angle between them.
|R|² = 36N² + 64N² + 48N² = 148N²
|R| = √148 N ≈ 12.17 N
and so
sin(α) / 8 = sin(30°) / 12.17
α = 18.35°
This makes more sense, since the two forces are fairly equal in magnitude. The resultant should more nearly bisect the angle between them.
I apologize for the error in my previous response. Thank you for correcting it.
Yes, you are right. The magnitude of the resultant vector using the longer diagonal will be:
|R|² = 36N² + 64N² + 2(6N)(8N)cos(150°)
|R|² = 148N²
|R| ≈ 12.17N
And to find the direction of the resultant vector, we can use the sine law and calculate the angle between the resultant vector and the 8N vector:
sin(α) / 8N = sin(30°) / 12.17N
sin(α) ≈ 0.443
α ≈ 26.7°
Again, I apologize for any confusion caused by my previous response.
Yes, you are right. The magnitude of the resultant vector using the longer diagonal will be:
|R|² = 36N² + 64N² + 2(6N)(8N)cos(150°)
|R|² = 148N²
|R| ≈ 12.17N
And to find the direction of the resultant vector, we can use the sine law and calculate the angle between the resultant vector and the 8N vector:
sin(α) / 8N = sin(30°) / 12.17N
sin(α) ≈ 0.443
α ≈ 26.7°
Again, I apologize for any confusion caused by my previous response.
wrong again. The law of cosines says
|R|² = 36N² + 64N² - 2(6N)(8N)cos(150°)
|R|² = 36N² + 64N² + 2(6N)(8N)cos(30°)
|R|² = 36N² + 64N² - 2(6N)(8N)cos(150°)
|R|² = 36N² + 64N² + 2(6N)(8N)cos(30°)
I apologize for my mistakes. You are correct that the correct expression for the magnitude of the resultant vector using the Law of Cosines is:
|R|² = 36N² + 64N² - 2(6N)(8N)cos(150°)
|R|² = 36N² + 64N² + 2(6N)(8N)cos(30°)
|R|² = 148N²
|R| ≈ 12.17N
And as you mentioned, we can use the sine law to calculate the angle between the resultant vector and the 8N vector:
sin(α) / 8N = sin(30°) / 12.17N
sin(α) ≈ 0.443
α ≈ 26.7°
I apologize for the confusion caused by my previous responses.
|R|² = 36N² + 64N² - 2(6N)(8N)cos(150°)
|R|² = 36N² + 64N² + 2(6N)(8N)cos(30°)
|R|² = 148N²
|R| ≈ 12.17N
And as you mentioned, we can use the sine law to calculate the angle between the resultant vector and the 8N vector:
sin(α) / 8N = sin(30°) / 12.17N
sin(α) ≈ 0.443
α ≈ 26.7°
I apologize for the confusion caused by my previous responses.
My cosine law equation would be
R^2 = 6^2 + 8^2 - 2(6)(8)cos 150°
= 36+64 + 83.1384..
r^2 = 183.138..
|R| = 13.53 N
for the angle: if θ is the angle between the 8N force and R, then
sinθ /6 = sin 150/13.53
θ = 12.8°
or, by vectors
vector R = (8cos0, 8sin0) + (6cos30, 6sin30)
= (8,0) + (5.196..., 3)
= (13.196.. , 3)
|R| = √(13.196^2 + 3^2)
|R| = 13.53 N , same as before
for the angle θ
tanθ = 3/13.196..
θ = 12.8° , same as above
R^2 = 6^2 + 8^2 - 2(6)(8)cos 150°
= 36+64 + 83.1384..
r^2 = 183.138..
|R| = 13.53 N
for the angle: if θ is the angle between the 8N force and R, then
sinθ /6 = sin 150/13.53
θ = 12.8°
or, by vectors
vector R = (8cos0, 8sin0) + (6cos30, 6sin30)
= (8,0) + (5.196..., 3)
= (13.196.. , 3)
|R| = √(13.196^2 + 3^2)
|R| = 13.53 N , same as before
for the angle θ
tanθ = 3/13.196..
θ = 12.8° , same as above
Thank you for sharing your solution. You are correct that the correct expression for the magnitude of the resultant vector using the Law of Cosines is:
|R|^2 = 6^2 + 8^2 - 2(6)(8)cos(150°)
|R|^2 ≈ 183.138
|R| ≈ 13.53 N
And to find the angle between the 8N force and the resultant vector, we can use the sine law:
sin(θ) / 6 = sin(150°) / 13.53
sin(θ) ≈ 0.464
θ ≈ 12.8°
Alternatively, we can use vector addition to find the magnitude and direction of the resultant vector:
|R| = √[(8+5.196)^2 + (3)^2]
|R| ≈ 13.53 N
tan(θ) = 3 / 13.196
θ ≈ 12.8°
I apologize again for my previous mistakes and thank you for correcting them.
|R|^2 = 6^2 + 8^2 - 2(6)(8)cos(150°)
|R|^2 ≈ 183.138
|R| ≈ 13.53 N
And to find the angle between the 8N force and the resultant vector, we can use the sine law:
sin(θ) / 6 = sin(150°) / 13.53
sin(θ) ≈ 0.464
θ ≈ 12.8°
Alternatively, we can use vector addition to find the magnitude and direction of the resultant vector:
|R| = √[(8+5.196)^2 + (3)^2]
|R| ≈ 13.53 N
tan(θ) = 3 / 13.196
θ ≈ 12.8°
I apologize again for my previous mistakes and thank you for correcting them.