Since (x,y)=(r\cos\theta,r\sin\theta) , the 2 curves can be given parametrically as \begin{align} \vec{r}_1 &= \big(a(1+\cos\theta)\cos\theta,a(1+\cos\theta)\sin\theta\big) \\ \vec{r}_2 &= ...

Prove the sharper inequality \sum_{i = 1}^k (1 - \cos \theta_i) \leqslant 1 - \cos \sigma_k for 1 \leqslant k \leqslant N, where \sigma_k = \sum_{i = 1}^k \theta_i. The base case is clear, ...

Call D the domain enclosed by your curve. Then, you're right, A=\text{Area}(D)=\iint_D\mathrm{d}A, where \mathrm{d}A is the surface element. In polar coordinates, D is represented by \Delta=\bigl\{(r,\theta)\in\mathbb{R}^2\;\bigm\vert\;0\leq\theta\leq2\pi,\ 0\leq r\leq2(1-\cos\theta)\bigr\}. ...

The tangents are given by \displaystyle\theta={0}\rightarrow{\quad\text{and}\quad}\leftarrow\theta=\pi . See the explanation, for this ticklish ...

Your limits are wrong, for example in the first integral you're integrating between r=0 and r=a instead of r=a(1+\cos\theta) and r=a. It also isn't clear what range you should take for \theta ...

\displaystyle\ \text{ }\ Please read the explanation. Explanation: \displaystyle\ \text{ }\ We have the Polar equation: \displaystyle{\left({r}={1}-{2}{\cos{{\left(\theta\right)}}}\right.} ...