## Calculation Breakdown

Set up the equation
$$1.0\left(milliradian\right)={\color{rgb(20,165,174)} x}\left(grad\right)$$
Define the base values of the selected units in relation to the SI unit $$\left(radian\right)$$
$$\text{Left side: 1.0 } \left(milliradian\right) = {\color{rgb(89,182,91)} 2.0 \times \dfrac{π}{6.4 \times 10^{3}}\left(radian\right)} = {\color{rgb(89,182,91)} 2.0 \times \dfrac{π}{6.4 \times 10^{3}}\left(rad\right)}$$
$$\text{Right side: 1.0 } \left(grad\right) = {\color{rgb(125,164,120)} \dfrac{π}{2.0 \times 10^{2}}\left(radian\right)} = {\color{rgb(125,164,120)} \dfrac{π}{2.0 \times 10^{2}}\left(rad\right)}$$
Insert known values into the conversion equation to determine $${\color{rgb(20,165,174)} x}$$
$$1.0\left(milliradian\right)={\color{rgb(20,165,174)} x}\left(grad\right)$$
$$\text{Insert known values } =>$$
$$1.0 \times {\color{rgb(89,182,91)} 2.0 \times \dfrac{π}{6.4 \times 10^{3}}} \times {\color{rgb(89,182,91)} \left(radian\right)} = {\color{rgb(20,165,174)} x} \times {\color{rgb(125,164,120)} {\color{rgb(125,164,120)} \dfrac{π}{2.0 \times 10^{2}}}} \times {\color{rgb(125,164,120)} \left(radian\right)}$$
$$\text{Or}$$
$$1.0 \cdot {\color{rgb(89,182,91)} 2.0 \times \dfrac{π}{6.4 \times 10^{3}}} \cdot {\color{rgb(89,182,91)} \left(rad\right)} = {\color{rgb(20,165,174)} x} \cdot {\color{rgb(125,164,120)} \dfrac{π}{2.0 \times 10^{2}}} \cdot {\color{rgb(125,164,120)} \left(rad\right)}$$
$$\text{Cancel SI units}$$
$$1.0 \times {\color{rgb(89,182,91)} 2.0 \times \dfrac{π}{6.4 \times 10^{3}}} \cdot {\color{rgb(89,182,91)} \cancel{\left(rad\right)}} = {\color{rgb(20,165,174)} x} \times {\color{rgb(125,164,120)} \dfrac{π}{2.0 \times 10^{2}}} \times {\color{rgb(125,164,120)} \cancel{\left(rad\right)}}$$
$$\text{Conversion Equation}$$
$$2.0 \times \dfrac{π}{6.4 \times 10^{3}} = {\color{rgb(20,165,174)} x} \times \dfrac{π}{2.0 \times 10^{2}}$$
Cancel factors on both sides
$$\text{Cancel factors}$$
$$\dfrac{{\color{rgb(255,204,153)} \cancel{π}} \times 2.0}{6.4 \times {\color{rgb(99,194,222)} \cancelto{10}{10^{3}}}} = {\color{rgb(20,165,174)} x} \times \dfrac{{\color{rgb(255,204,153)} \cancel{π}}}{2.0 \times {\color{rgb(99,194,222)} \cancel{10^{2}}}}$$
$$\text{Simplify}$$
$$\dfrac{2.0}{6.4 \times 10.0} = {\color{rgb(20,165,174)} x} \times \dfrac{1.0}{2.0}$$
Switch sides
$${\color{rgb(20,165,174)} x} \times \dfrac{1.0}{2.0} = \dfrac{2.0}{6.4 \times 10.0}$$
Isolate $${\color{rgb(20,165,174)} x}$$
Multiply both sides by $$\left(\dfrac{2.0}{1.0}\right)$$
$${\color{rgb(20,165,174)} x} \times \dfrac{1.0}{2.0} \times \dfrac{2.0}{1.0} = \dfrac{2.0}{6.4 \times 10.0} \times \dfrac{2.0}{1.0}$$
$$\text{Cancel}$$
$${\color{rgb(20,165,174)} x} \times \dfrac{{\color{rgb(255,204,153)} \cancel{1.0}} \times {\color{rgb(99,194,222)} \cancel{2.0}}}{{\color{rgb(99,194,222)} \cancel{2.0}} \times {\color{rgb(255,204,153)} \cancel{1.0}}} = \dfrac{2.0 \times 2.0}{6.4 \times 10.0 \times 1.0}$$
$$\text{Simplify}$$
$${\color{rgb(20,165,174)} x} = \dfrac{2.0 \times 2.0}{6.4 \times 10.0}$$
Solve $${\color{rgb(20,165,174)} x}$$
$${\color{rgb(20,165,174)} x} = 0.0625 = 6.25 \times 10^{-2}$$
$$\text{Conversion Equation}$$
$$1.0\left(milliradian\right) = {\color{rgb(20,165,174)} 6.25 \times 10^{-2}}\left(grad\right)$$