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LINE INTEGRAL IN A SCALAR FIELD MOTIVATION A rescue team follows a path in a danger area where for each position the degree of radiation is defined. Compute.

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Presentation on theme: "LINE INTEGRAL IN A SCALAR FIELD MOTIVATION A rescue team follows a path in a danger area where for each position the degree of radiation is defined. Compute."— Presentation transcript:

1 LINE INTEGRAL IN A SCALAR FIELD MOTIVATION A rescue team follows a path in a danger area where for each position the degree of radiation is defined. Compute the total amount of radiation gathered by the rescue team along the path. RESCUE BASE

2 Line integral I Line integral in a scalar field Line integral in a vector field

3 SCALAR FIELD Let P be a planar contiguous area with a function defined on it. We calla scalar field defined over M Similarly, for a 3D area V, we define a scalar field as a function with the domain V. P V temperature, radiation, moisture, mass,...

4 Let a scalar field f(x,y) be defined in a planar area M. Let L be a regular curve defined by the parametric equations Define a partition of T: Choose pointssuch that Put is called the norm of the partition. Put

5 M... L0L0 a=a 0 a 1 a 2 a 3 a n-1 a n =b...  1  2  3  n L1L1 L2L2 L3L3 L n-1 LnLn

6 We can define the following integral sum If, forwe have for some finite L 0, we say that L 0 is the line (or curvilinear) integral of the scalar field f(x,y) over L (line integral of the first type). Symbolically, we write

7 is independent of the way the partition of If f(x,y) is continuous on a regular curve L given by the parametric equations [a,b] is constructed and the numberschosen. then the following formula can be used or if L is given by the explicit equation y=g(x).

8 For a 3D-area V, a scalar field f(x,y,z), and a 3D-curve L the line integral is defined in much the same way. If f(x,y,z) is continuous on L given by If we recall the way the length of a curve is defined, we see that ds actually denotes the differential of the length of L. we can use the formula

9 EXAMPLE Calculatewhere C is the first turn of the helix In the plot below, we have a=2 and b=0.3 [x,y,z][x,y,z]

10

11 EXAMPLE Find the centre of mass of the first half-arch of the cycloid if its specific mass is constant.

12 The centre of mass of a curve is defined in physics as the point T=[t x,t y ] that has the following property: if the entire mass of the curve was concentrated at T, its torque with respect to axes x, y would be equal to the torque with respect to axes x, y of all the points added up. This means that

13 whereand whereand

14

15

16 LINE INTEGRAL IN A VECTOR FIELD MOTIVATION A ship sails from an island to another one along a fixed route. Knowing all the sea currents, how much fuel will be needed ?

17 VECTOR FIELD Let P be a planar contiguous area with a vector function defined for each P V water flow, electromagnetic field,... We say that f(x,y) is a vector field defined on P. Similarly, is a vector field defined in a 3D area V.

18 Let a vector field f(x,y) be defined on a planar area M. Let L be an oriented regular curve defined by the parametric equations Define a partition of T: Choose pointssuch that Put is called the norm of the partition. Put

19 M... L0L0 a=a 0 a 1 a 2 a 3 a n-1 a n =b...  1  2  3  n L1L1 L2L2 L3L3 L n-1 LnLn

20 Define the following integral sum If, forwe have for some finite L 0, we say that L 0 is the line (or curvilinear) integral of the vector field f(x,y) over L (line integral of the second type). Symbolically, we write or

21 is independent of the way we construct the partition of [a,b] and choose the numbers To calculate the line integral we can use the formula where  is 1 if the curve is oriented in correspondence with its parametric equations otherwise it is equal to –1.

22 For a 3D-area V, a vector field f(x,y,z), and a 3D-curve L the line integral is defined in much the same way with the following formula for calculating a 3D line integral: Line integral of the second type clearly depends on the way the curve is oriented and ds actually denotes the differential of the tangent vector field along L.

23 EXAMPLE Calculate where L is the first turn of the helix oriented in correspondence with the parametric equations a=2 and b=0.3 [x,y,z][x,y,z]

24

25 EXAMPLE where C is a circle given by the parametric equations R  x y z oriented in correspondence with them. Calculate

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27 EXAMPLE Determine the work done by the elasticity force if the vector of this force at each point is directed towards the origin its module being proportionate to the distance from the origin of the point and if the application point of the force moves anticlockwise along the quarter of the ellipse that lies in the first quadrant. a b

28 where and L is given by the parametric equations tends to zero as the ellipse tends to circle

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