Do you mean the y-component of the tangent vector? In that case yes. It would only be a reparametrisation of the line.Physics345 said:basically in this case y can equal anything except for 0 for it to be parallel to the y-axis?
Orodruin said:Do you mean the y-component of the tangent vector? In that case yes. It would only be a reparametrisation of the line.
As for the y-value of the line, it can take any value - including 0 - depending on the value of the curve parameter.
It is exactly what he did.Tonyb24 said:if it passes through that point, then why not use that point as the support point?
Again, it is exactly what he did.Tonyb24 said:Then, what is a point on the Y axis that you can multiply to reach any y-axis point?
Which is exactly what he got:Tonyb24 said:So now, use your support point P and add to it a vector that can be multiplied by t where t E R, that will allow you to reach anypoint on the line (like a unit vector or something). L:(x,y,z)=P+t(x,y,z);t E R.
Physics345 said:(x,y,z)=(-1,0,3)+t(0,1,0)
A parallel vector equation is a mathematical representation of two or more vectors that have the same direction but may differ in magnitude. This is commonly used in physics and engineering to describe the motion or forces acting on an object.
To write a parallel vector equation, first determine the direction of the vectors. This can be done by finding the slope or using the direction angles. Then, use the direction and magnitude of one vector to write the equation in the form r = r0 + tv, where r0 is a known point on the line and v is the direction vector. Repeat this process for any additional vectors.
A parallel vector equation describes the direction and magnitude of vectors, while a linear equation describes a straight line. In a parallel vector equation, the direction vectors may be parallel but not necessarily collinear, whereas in a linear equation, all points on the line are collinear.
Yes, a parallel vector equation can have any number of vectors. The equation would be written as r = r0 + tv1 + sv2 + uv3 + ..., where v1, v2, v3, etc. are the direction vectors and t, s, u, etc. are the corresponding scalar values.
A parallel vector equation is used in a variety of real-life applications, such as describing the motion of objects in physics, calculating forces in engineering, and modeling trajectories in computer graphics. It is also used in navigation to calculate the direction and distance between two points.