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Tangent vectors, or....... Copyright 2008 by Evans M. Harrell II. MATH 2401 - Harrell
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Tangent vectors, or how to go straight when you are on a bender. Copyright 2008 by Evans M. Harrell II. MATH 2401 - Harrell
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In our previous episode: 1.Vector functions are curves. The algebraic side of the mathematian’s brain thinks about vector functions. The geometric side sees curves.
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In our previous episode: 1.Vector functions are curves. 2.Don’t worry about the basic rules of calculus for vector functions. They are pretty much like the ones you know and love.
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The good news: The rules of vector calculus look just like the rules of scalar calculus Chain rule (f(u(t))) = u(t) f(u(t)) Example: If u(t) = t 2 and f(x) = sin(x)i - 2 x j, Example: If u(t) = t 2 and f(x) = sin(x)i - 2 x j, then f(u(t)) = sin(t 2 )i - 2 t 2 j, and its derivative: 2 t cos(t 2 )i - 4 t j is equal to 2 t (cos(x)i - 2j) when we substitute x = t 2. 2 ways to calculate: substitute and then differentiate, or chain rule
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circles and ellipses spirals helix Lissajous figures Some great curves and how to write them as parametrized curves
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Tangent vectors – the derivative of a vector function
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Tangent vectors Think velocity!
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Tangent vectors Think velocity!
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Tangent vectors Think velocity!
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Tangent vectors Think velocity!
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Tangent vectors Think velocity! Tangent lines
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Tangent vectors Think velocity! Tangent lines Tell us more about these!
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Tangent vectors The velocity vector v(t) = r(t) is tangent to the curve – points along it and not across it.
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Example: spiral
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Curves Position, velocity, tangent lines and all that: See Rogness applets (UMN).Rogness applets (UMN).
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Tangent vectors Think velocity! Tangent lines Approximation and Taylor’s formula
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Tangent vectors Think velocity! Tangent lines Approximation and Taylor’s formula Numerical integration
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Tangent vectors Think velocity! Tangent lines Approximation and Taylor’s formula Numerical integration Maybe most importantly – T is our tool for taking curves apart and understanding their geometry.
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Example: helix
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Example: Helix
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Unit tangent vectors Move on curve with speed 1.
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Unit tangent vectors Move on curve with speed 1. T(t) = r(t)/ |r(t)|
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Unit tangent vectors Move on curve with speed 1. T(t) = r(t)/ |r(t)| Only 2 possibilities, ± T.
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Example: ellipse
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Example: spiral
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Example: Helix
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Curves Even if you are twisted, you have a normal!
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Normal vectors A normal vector points in the direction the curve is bending. It is always perpendicular to T. What’s the formula?……………
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Normal vectors N = T/||T||. Unless the curve is straight at position P, by this definition N is a unit vector perpendicular to T. Why?
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Example: spiral in 3D
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Interpretation. Notice that the normal vector has no vertical component. This is because the spiral lies completely in the x-y plane, so an object moving on it is not accelerated vertically.
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Example: Helix
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Interpretation. Notice that the normal vector again has no vertical component. If a particle rises in a standard helical path, it does not accelerate upwards of downwards. The acceleration points inwards in the x-y plane. It points towards the central axis of the helix.
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Example: solenoid
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Scary, but it might be fun to work it out!
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Arc length If an ant crawls at 1 cm/sec along a curve, the time it takes from a to b is the arc length from a to b.
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Arc length If an ant crawls at 1 cm/sec along a curve, the time it takes from a to b is the arc length from a to b. More generally, ds = |v(t)| dt
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Arc length If an ant crawls at 1 cm/sec along a curve, the time it takes from a to b is the arc length from a to b. More generally, ds = |v(t)| dt In 2-D ds = (1 + y’ 2 ) 1/2 dx, or ds 2 = dx 2 + dy 2 or…
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Arc length
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∞ – fifl ‚— œ∑ “‘ Œ„ ∏”’ ’ ” ∂ƒ ∆ √ ◊
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