For the development of the Internet of Things (IoT), wearable devices, and implantable medical devices, the wireless power transmission is receiving significant attention. In these applications, the external power from a transmitter is transmitted by the coils / antennas, and an AC voltage will be received in a wireless device. In the traditional wireless power transfer systems, the AC-DC conversion systems followed by the DC-DC conversion systems are used to generate an accurate voltage to safely charge a battery. Recently, the current-mode wireless power receivers are presented. By charging the battery with inductor current, the current-mode wireless power systems avoid rectification and voltage regulation. Therefore, the DC-DC conversion systems are spared and the PCE is improved. Also, the chip area and the off-chip components are reduced. This thesis presents a 13.56MHz current-mode wireless power receiver with energy-investment capability. When the system is in the charging mode, this work does not charge the output battery with all the power in the LC tank as the state-of-the-art systems do, this work reserves a fraction of energy stored as an investing voltage in the resonate capacitor instead. The investing voltage gives an initial voltage of the coil when this work finishes charging and starts to accumulate energy. The investing voltage increases the ability to grab energy from electromotive force (EMF). This work employs sample and holds circuits (SAHs) with low-frequency clocks to sample voltage and digital controlled delay lines (DCDLs) to control the switching timing of the power MOS. By this way, the operation frequency can be raised to 13.56MHz. High bandwidth circuits are avoided in the control circuits and power is saved. This work is fabricated in a 0.18-µm CMOS process and the active area is 0.341mm2. It achieves a peak PCE of 67.1% when the input power is 6mW.