Commercial off-the-shelf (COTS) heterogeneous multiple processors systems-on-chip (MPSoCs) are appealing platforms for emerging mixed criticality systems (MCSs). To satisfy MCS requirements, the platform must guarantee predictable timing bounds for critical applications, without degrading average performance for noncritical applications. In particular, this paper studies the main memory subsystem, which in modern MPSoCs is typically based on double data rate synchronous dynamic access memory. While there exists previous work on worst-case DRAM latency analysis, such work only covers a small subset of possible COTS configurations, which are not targeted at MCS. Therefore, we derive a generalized interference delay analysis for DRAM main memory that accounts for a breadth of features deployed in COTS platforms. We then explore the design space by studying the effects of each feature on both the worst-case delay for critical applications, and the bandwidth for noncritical applications.