Example about tangential and normal unit vectors

In summary, the conversation discusses the process of finding the radius of curvature and unit vectors in the normal and tangential directions for a particle moving on a path defined by a curve. The individual discussing their approach to finding the unit vectors and the discrepancies they encountered when compared to the solution in a book. The main point of discussion is the importance of considering the derivative of the velocity and its impact on the direction of the unit vectors. Ultimately, the conversation highlights the complexity of finding these vectors and the various factors that must be taken into account.
  • #1
mech-eng
828
13
Here is a example 1.3 from analytical dynamics of Haim Baruh.
a particle moves on a path on the xy plane defined by the curve y=3*x^2 , where x varies with the relation x= sin(a). find the radius of curvature of the path and unit vectors in the normal and tangential directions when a=pi/6. This is example with solution but I tried another way to find unit vectors.I have find the tangential vector true but normal vector was wrong but I don't know where I am wrong. Can you help me please.

First I have tried to find tangential vector. r=sin(a)i + 3(sin(a))^2j as in the solution. Then I thought unit tangential unit vector must be in the direction of tangent to the path which is the same as derivative of position vector r. its derivative I found is cos(a) i + 6sin(a)cos(a)j. then I calculated derivative vector at a=pi/6 as sqrt(3)/2 i + 3/2 sqrt(3) j, which is the same as in the book. Then I have calculated the magnitude of derivative of position vector and then calculated its unit vector as the tangential vector. This was true result. But when calculating normal unit vector something is wrong. While calculating normal unit vector first I thought that it is orthogonal to the tangential unit vector and if I take derivative of tangential unit vector must be in the direction of normal unit vector. I thought derivative of tangential unit vector must be in the same direction with second derivative of position vector which is -sin(a)i + -6sin(a)cos(a)j. Then I have calculated second derivative vector at pi/6 as -1/2i + -2.59808 j. Then I calculate the magnitude as sqrt(7) and unit vector in the normal direction as (-1/2)/sqrt(7)i + -2.59808/sqrt(7) which is -0.18898i+ -0.98198 j. But solution for normal unit vector in the book is -0.9487i+0.3162j. I can't understand what is wrong for my solution.
 
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  • #2
The second derivative of the position gives you the derivative of the velocity. The velocity has the same direction as the tangential unit vector but different magnitude. Notably, the magnitude of the velocity may change over time. if v is the velocity vector, v its magnitude, and ut the tangential unit vector than we have

v = v ut, and

d/dt v = v d/dt ut + (dv/dt) ut

The second term in the last equation has the wrong direction and will skew your final reasult
 
  • #3
You don't need to take the derivative of the unit tangent vector to get the unit normal vector, although that will certainly give you the unit normal. Don't forget that the unit normal is perpendicular to the unit tangent, so their dot product must be zero. So, if the unit tangent has components (a,b), the unit normal must have components (-b,a) or (b,-a).

Chet
 
  • #4
Chestermiller said:
You don't need to take the derivative of the unit tangent vector to get the unit normal vector, although that will certainly give you the unit normal. Don't forget that the unit normal is perpendicular to the unit tangent, so their dot product must be zero. So, if the unit tangent has components (a,b), the unit normal must have components (-b,a) or (b,-a).

Chet


Your approach is really good and very practical. First derivative is velocity and in the tangential direction but should not second derivative which is also derivative of velocity be orthogonal to first derivative. We should also
consider the fact that derivative of a unit vector is orthogonal to itself.
 
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  • #5
dauto said:
The second derivative of the position gives you the derivative of the velocity. The velocity has the same direction as the tangential unit vector but different magnitude. Notably, the magnitude of the velocity may change over time. if v is the velocity vector, v its magnitude, and ut the tangential unit vector than we have

v = v ut, and

d/dt v = v d/dt ut + (dv/dt) ut

The second term in the last equation has the wrong direction and will skew your final reasult

But how about unit vector of first derivative in your last equation? I think it is normal vector. Yes it is magnitude
may change over time but we are dealing with when a=pi/6 and note that second derivative in my first post is
wrongly calculated, sorry for it. but my question still continues from derivative perspective.
 
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  • #6
mech-eng said:
Your approach is really good and very practical. First derivative is velocity and in the tangential direction but should not second derivative which is also derivative of velocity be orthogonal to first derivative. We should also
consider the fact that derivative of a unit vector is orthogonal to itself.
If the magnitude of the velocity vector is changing, the derivative of the velocity vector has two components, one in the direction parallel to the velocity vector and the other in the direction normal to the velocity vector. This is what dauto's post was saying. However, if you first evaluated the velocity vector, and then divided it by its own magnitude, you would have a unit vector pointing in the same direction as the velocity vector. The derivative of this unit vector would be a unit vector normal to the velocity vector.

Chet
 
  • #7
Chestermiller said:
If the magnitude of the velocity vector is changing, the derivative of the velocity vector has two components, one in the direction parallel to the velocity vector and the other in the direction normal to the velocity vector. This is what dauto's post was saying. However, if you first evaluated the velocity vector, and then divided it by its own magnitude, you would have a unit vector pointing in the same direction as the velocity vector. The derivative of this unit vector would be a unit vector normal to the velocity vector.

Chet

But aren't first taking derivative then finding unit vector and first finding unit vector then taking
derivative the same things?
 
  • #8
mech-eng said:
But aren't first taking derivative then finding unit vector and first finding unit vector then taking
derivative the same things?
No they aren't. Suppose the particle is accelerating in a straight line. What is the time derivative of the velocity vector? Does it have a component tangent to the velocity vector?

Chet
 
  • #9
Chestermiller said:
No they aren't. Suppose the particle is accelerating in a straight line. What is the time derivative of the velocity vector? Does it have a component tangent to the velocity vector?

Chet


Thank you for this very instructive example. My another question is why do we calculate radius of curvature and torsion of the curve?
 
  • #10
mech-eng said:
Thank you for this very instructive example. My another question is why do we calculate radius of curvature and torsion of the curve?
These are used to determine the components of the net forces acting on the particle, in conjunction with writing the force balance equations.

Chet
 

Related to Example about tangential and normal unit vectors

1. What is a tangential unit vector?

A tangential unit vector is a vector that is tangent to a curve or surface at a specific point. It represents the direction of motion or change in direction at that point.

2. How is a tangential unit vector different from a normal unit vector?

A normal unit vector is perpendicular to a curve or surface at a specific point, while a tangential unit vector is tangent to the curve or surface at that point. They represent two different aspects of motion or change in direction.

3. How are tangential and normal unit vectors used in physics?

In physics, tangential and normal unit vectors are used to analyze the motion of objects along curved paths or surfaces. They help to determine the direction and magnitude of acceleration, as well as the direction of forces acting on an object.

4. Can tangential and normal unit vectors be used in three-dimensional space?

Yes, tangential and normal unit vectors can be used in three-dimensional space. In this case, they represent the direction of motion or change in direction along a curved surface or in a curved space.

5. How are tangential and normal unit vectors calculated?

Tangential and normal unit vectors can be calculated using calculus and vectors. For a given curve or surface, the tangential unit vector is the derivative of the position vector with respect to arc length, while the normal unit vector is the derivative of the tangential unit vector with respect to arc length.

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