Implementation of modern digital transceivers requires an expertise in numerous fields. Conventional transceiver design methods are no longer sufficient to guarantee a fast conversion from initial concept to final product. Moreover, in the testing phase, system simulations alone cannot provide the full insight into the system parameters and performance, especially at the RF stages, where the modeling of power amplifier non-linearities is a highly complex task. To address these design gaps, this paper utilizes software radio solutions. Specifically, it elaborates on transceiver architectural methods at the baseband involving hardware/software partitioning, as well as automatic digital signal processing (DSP) coding strategies that allow for rapid prototyping, testing and verification of algorithms developed in the design simulation stages. In particular, DSP processor and field programable gate array (FPGA)-based testbeds are described that offer different advantages in the transceiver rapid prototyping methodology. These testbeds were designed to eventually be used in experiments geared towards demonstrating the effectiveness of compensation algorithms for wireless systems like wireless local area network (WLAN) and digital audio broadcasting (DAB), where orthogonal frequency division multiplexed (OFDM) signaling is deployed.