This is how I like to write these out. The value of $x^2 - d y^2$ for $x=p$ and $y=q$ is written directly below each convergent $\frac{p}{q}.$ I recommend that you practice writing yours the same way, it helps to see that the values of $x^2 - d y^2$ also repeat in absolute value but have a $\pm$ switch when there does exist a solution to $x^2 - d y^2 = -1;$ so first we find $70^2 - 29 \cdot 13^2 = -1,$ only later do we find $9801^2 - 29 \cdot 1820^2 = 1.$
$$ \sqrt {29} $$
$$
\begin{array}{cccccccccccccccccccccccccccccc}
& & 5 & & 2 & & 1 & & 1 & & 2 & & 10 & & 2 & & 1 & & 1 & & 2 & & 10 & \\
\frac{0}{1} & \frac{1}{0} & & \frac{5}{1} & & \frac{11}{2} & & \frac{16}{3} & & \frac{27}{5} & & \frac{70}{13} & & \frac{727}{135} & & \frac{1524}{283} & & \frac{2251}{418} & & \frac{3775}{701} & & \frac{9801}{1820} & & \frac{101785}{18901} \\
\\
-29 & 1 & & -4 & & 5 & & -5 & & 4 & & -1 & & 4 & & -5 & & 5 & & -4 & & 1 & & -4
\end{array}
$$
We begin with two fake "convergents," first "$p/q = 0/1,$" and below that $0^2 - 29 \cdot 1^2 = -29.$ Next, "$p/q = 1/0,$" and below that $1^2 - 29 \cdot 0^2 = 1.$
Then our first genuine convergent, $p/q = 5/1,$ and below that $5^2 - 29 \cdot 1^2 = -4.$ Next, $p/q = 11/2,$ and below that $11^2 - 29 \cdot 2^2 = 5.$
A few steps later, $p/q = 70/13,$ and below that $70^2 - 29 \cdot 13^2 = -1.$
Several more steps later, $p/q = 9801/1820,$ and below that $9801^2 - 29 \cdot 1820^2 = 1.$
Smaller displays so that the entire calculation might fit in the intended width:
First we use the command "small:"
$$
\small
\begin{array}{cccccccccccccccccccccccccccccc}
& & 5 & & 2 & & 1 & & 1 & & 2 & & 10 & & 2 & & 1 & & 1 & & 2 & & 10 & \\
\frac{0}{1} & \frac{1}{0} & & \frac{5}{1} & & \frac{11}{2} & & \frac{16}{3} & & \frac{27}{5} & & \frac{70}{13} & & \frac{727}{135} & & \frac{1524}{283} & & \frac{2251}{418} & & \frac{3775}{701} & & \frac{9801}{1820} & & \frac{101785}{18901} \\
\\
-29 & 1 & & -4 & & 5 & & -5 & & 4 & & -1 & & 4 & & -5 & & 5 & & -4 & & 1 & & -4
\end{array}
$$
now scriptsize
$$
\scriptsize
\begin{array}{cccccccccccccccccccccccccccccc}
& & 5 & & 2 & & 1 & & 1 & & 2 & & 10 & & 2 & & 1 & & 1 & & 2 & & 10 & \\
\frac{0}{1} & \frac{1}{0} & & \frac{5}{1} & & \frac{11}{2} & & \frac{16}{3} & & \frac{27}{5} & & \frac{70}{13} & & \frac{727}{135} & & \frac{1524}{283} & & \frac{2251}{418} & & \frac{3775}{701} & & \frac{9801}{1820} & & \frac{101785}{18901} \\
\\
-29 & 1 & & -4 & & 5 & & -5 & & 4 & & -1 & & 4 & & -5 & & 5 & & -4 & & 1 & & -4
\end{array}
$$
Next we use "tiny"
$$
\tiny
\begin{array}{cccccccccccccccccccccccccccccc}
& & 5 & & 2 & & 1 & & 1 & & 2 & & 10 & & 2 & & 1 & & 1 & & 2 & & 10 & \\
\frac{0}{1} & \frac{1}{0} & & \frac{5}{1} & & \frac{11}{2} & & \frac{16}{3} & & \frac{27}{5} & & \frac{70}{13} & & \frac{727}{135} & & \frac{1524}{283} & & \frac{2251}{418} & & \frac{3775}{701} & & \frac{9801}{1820} & & \frac{101785}{18901} \\
\\
-29 & 1 & & -4 & & 5 & & -5 & & 4 & & -1 & & 4 & & -5 & & 5 & & -4 & & 1 & & -4
\end{array}
$$
That is pretty good, please concentrate on the line of $x^2 - d y^2$ values, maybe ignore the initial $-29,$ so
$$ 1, \; -4, \; 5, \; -5, \; 4, \; -1, \; 4, \; -5, \; 5, \; -4, \; 1, \; -4, \ldots $$
I got instructions on re-sizing Latex at What are some options for putting another, smaller copy of this long Latex item?
