It is hard to be sure that I am doing this correctly when I have no idea what any of the variables represent. In fact, you have not even bothered to tell us what are variables and what are constants. Moreover, the utility equation has a very strange symbol in it. How many variables are we dealing with? Is BC an abbreviation for Before Christ? We are not mind readers.
It looks like a utility maximization problem subject to a budget constraint.
Consider the problem: maximize u subject to the constraint that [imath]c_1 - c_2/R - y_1 - y_2/R = 0[/imath], where all variables are positive and y_1, y_2, and R are constants.
[math]L(c_1, \ c_2) = \ln(c_1) + \beta \ln(c_2) - \lambda * \left ( c_1 - \dfrac{c_2}{R} - c_2 - y_1 - \dfrac{y_2}{R} \right ) \implies \\
\dfrac{\delta L}{\delta c_1} = 0 \implies \dfrac{1}{c_1} - \lambda = 0; \\
\dfrac{\delta L}{\delta c_2} = 0 \implies \dfrac{\beta}{c_2} - \lambda = 0; \text { and }\\
\dfrac{\delta L}{\delta \lambda} = 0 \implies c_1 - \dfrac{c_2}{R} - y_1 - \dfrac{y_2}{R}.
[/math]
Eliminating lambda from the first two partials gives
[math]\dfrac{1}{c_1} - \dfrac{\beta}{c_2} = 0 \implies c_2 = \beta c_1.[/math]
But that does not match what you say the answer is.
In your very first equation should it be
[math]u = c_1 + \dfrac{\beta c_2}{R}[/math]
please try to clarify the question.