With the change in social types, health issues have become the focus of attention, and exercise has become a trend. Regular and moderate activities can bring benefits to health, but improper exercise may cause fatigue and even injury to the body. When the human body performs dailylife activities, the plantar of the feet bear the load of the body weight. Through the pressure changes of the plantar, it is possible to observe whether occurs abnormal pressure distribution or regional high pressure. In addition, with the rapid aging of the population, the elderly and many patients with neurological diseases often suffer from gait disorder, which is prone to falls and reduces the ability to do activities of daily living. To prevent exercise injuries and to observe gait problems caused by aging and neurological diseases, daily monitoring of plantar pressure becomes important for pressure detection and gait analysis. Therefore, this study develops a multi-channel plantar pressure monitoring system for daily activities. A wearable wireless recording system displays the changes in plantar pressure at different positions of the plantar during daily activities. The system uses a multiplexer to input multi-channel pressure signals, and thus reduces the weight of the hardware circuit and power consumption of the amplifier circuit. Subsequently, multi-channel pressure signals were obtained by using a demultiplexer. Among them, the buffer circuit is used to adjust the DC offset voltage and to control the quiescent current, and adequate operational amplifiers were selected to design the amplifier and low-pass filter. Circuit configuration, component selection, measurement location of plantar pressure, and numbers of the pressure sensors are carefully considered during the design phase and are described in detail in this thesis. For wearable purpose, the system design takes lightweight and power saving into consideration. The system is powered by a single battery power, the reference potential is set to around a half of the battery potential, and the quiescent current of the overall system is determined by using discrete transistors. Therefore, the characteristics of lightweight and power saving can be achieved simultaneously. Furthermore, wireless transmission is realized through the Bluetooth of the microcontroller module, and a simple user interface is designed in the MATLAB environment on the computer end to provide visual feedback of the plantar pressures. Then, laying the foundation for daily activity monitoring and subsequent analysis of plantar pressure. It is expected that the developed multi-channel plantar pressure portable wireless transmission system can be used for daily monitoring and reduce the risk of exercise injuries. After further gait analysis, it can be used in clinical applications as a quantitative tool for diagnosing the progression of gait disorders, drug reactions, and even predicting falls. Reducing the chances of injury and medical treatment in the elderly and those with neurological diseases, and maintaining the ability to perform activities of daily living.