Hello all,
I am dealing with some SDP optimization, and I come across the following problem.
The optimization problem is given by
\begin{aligned} &\operatorname*{min}_{t_1,\ldots,t_m,X}\ \sum t_i \\\ &\;\text{s.t.}\ \ \begin{bmatrix} A(X)+B & e_i \\\ e_i^T & t_i \end{bmatrix} \succeq 0,\ \ \ i=1,\ldots,m\ \ \ \ \ \\\ &\ \ \ \ \ \ \ \;X\succeq 0,\ \ \ \ \ \ \ \text{trace}(X) = C \end{aligned}
where $X\in\mathbb{R}^n$, $(t_i)_{i=1}^m$ are postive scalar, and $e_i$ is the unit vector in $\mathbb{R}^m$. It is known that the both matrices $A$ (for every $X$) and $B$ are positive definite. Also, it's known that $A(X)$ is a linear function in $X$, and hence this optimization problem is convex. Note that $B$ is independent on $X$ and on $(t_i)_i$.
My question: is it true that the above minimization has the same optimal solution, $X^o$, which the following minimization problem has ("just" ignoring $B$)
\begin{aligned} &\operatorname*{min}_{t_1,\ldots,t_m,X}\ \sum t_i \\\ &\;\text{s.t.}\ \ \begin{bmatrix} A(X) & e_i \\\ e_i^T & t_i \end{bmatrix} \succeq 0,\ \ \ i=1,\ldots,m\ \ \ \ \ \\\ &\ \ \ \ \ \ \ \;X\succeq 0,\ \ \ \ \ \ \ \text{trace}(X) = C. \end{aligned}
If I am not wrong, a feasible solution of the second problem is also feasible for the first one. But, are these two problems has the same solution $X^o$?
