Due to continuous flourish of portable embedded systems, related electronics are widely developing in our daily life, such as communication, education, entertainment, biomedical measurement, and etc. In addition to on-going innovative features and miniaturization, design orientation is how to extend the standby interval in these embedded systems for power saving, which has become a critical design issue. Therefore, power management unit with power management strategy in portable embedded system-on-a-chip (SoC) applications becomes a very essential design area. Small-volume power management unit with power management strategy not only needs to keep the characteristics of high-quality conversion efficiency, but also considers real-time overall embedded system dynamic workload to adaptively optimize output power. It can lead to significant improvement in service time of portable electronics. Here, the exact control source of the dynamic workload is core component of portable embedded systems, which is digital signal processor (DSP) or microprocessor. Conventional task-based dynamic voltage scaling (DVS) power management strategy allows all tasks in a scheduler to complete just-in-time operations. Thus, the operating system (OS) depends on run-time workload and dynamically adjusts the power module output voltage, thereby leading to substantial power saving in processor. Unfortunately, conventional task-based DVS fails to operate if the microprocessor has no slack time. To overcome the limitation, this thesis proposed an instruction-cycle-based dynamic voltage scaling (iDVS) power management strategy with swift response and low quiescent current lattice asynchronous self-timed control digital low-dropout (LASC DLDO) regulator for low-power processor designs. Experiment results show that the iDVS-based DSP chip achieves 53% power saving. On the other hand, Class-D amplifiers are prevalent in portable audio embedded systems due to high power efficiency. Thus, battery lifetime can be extended and thermal dissipation can be reduced. This thesis also presented a differential interpolation pulse-width modulation (iPWM) based Class-D acoustic amplifier for multimedia embedded SoC systems. Without noise shaping feedback loop, the iPWM based Class-D modulator can have 108 dB signal-to-noise ratios (SNR). It also implies that modulator is always stable for full-swing input audio signal corresponding to modulation index approximately equal to one. Experimental results demonstrate that iPWM maximizes Class-D switching amplifier output power with 2.2 times that of traditional digital sigma-delta modulator based Class-D amplifier with modulation index 0.5. In system-level and circuit-level perspectives, the proposed power module and power management strategy are all implemented in fully digital standard complementary metal oxide semiconductor (CMOS) process. Experimental results show that it is appropriate for highly integrated SoC as well as for advance sub-micrometer chip power management module embedded system integration.