Sketching curves the curve r = asin 2θ

Sketching curves the curve r = asin 2θ

Sketching Curves with the Equation r = asin 2θ

Understanding the Equation

  • The equation r = asin 2θ is a common form of polar representation of ellipses or curves. It is defined by two variables: ‘r’ which is the distance from the origin (O), and ‘θ’ which is the angle from the positive x-axis.

  • ‘a’ is the amplitude of the curve and ‘2θ’ suggests a repeated pattern, or loop, every π radians (or 180 degrees), rather than the usual 2π radians (or 360 degrees) in a full revolution. This indicates a form of doubling effect on the curve.

  • Having a positive ‘a’ results in a curve above the initial axis while having a negative ‘a’ will produce a curve below the initial axis.

Sketching the Curve

  1. Identify the range of θ: As it’s a form of ellipse, θ varies from 0 to 2π.

  2. Calculate r for key points θ: Calculate ‘r’ for key values of ‘θ’. These commonly include θ = 0, π/2, π, 3π/2 and 2π.

  3. Plot the points and sketch the curve: Plot the coordinated points (r, θ) for ‘r’ against ‘θ’ on the polar grid or Cartesian plane and join the dots to sketch the curve.

  • Remember, when ‘r’ is negative, the point plotted is actually on the opposite side of the origin from the direction θ implies.

Features of the Curve

  • The curve represented by the equation r = asin 2θ is symmetric about the initial line (line at θ = 0) as sine is an odd function.

  • It forms a cardioid like shape with a loop. The size of the loop depends on the amplitude ‘a’.

  • In half a rotation (π radians or 180 degrees), the curve makes a full loop. Then in the second half of the rotation, it retraces exactly the same loop. Hence, it actually completes two full loops in one full revolution.

Example

  • Consider the example of r = 3sin 2θ. Plotting the key values and sketching the curve would give you two loops each extending 3 units from the origin, forming a sort of four-leaf clover shape.

  • Upon sketching, you can clearly see the symmetry about the initial line and the doubling of loops as implied by the ‘2θ’.