The paper presents an innovative power generation system that utilizes piezoelectric sensors to convert footstep pressure into electrical energy. The system, designed for public spaces like bus stands, railway stations, and shopping malls, consists of piezoelectric sensors, an Arduino UNO, an LCD display, a PIC microcontroller, voltage boosters, a battery, an LDR, and a socket for mobile charging. When footsteps apply pressure on the sensors, they generate voltage, which is then converted into electrical power. The system aims to reduce reliance on conventional power sources and conserve natural resources. The maximum voltage generated per step is 22 volts, and the minimum is 1 volt. In a 24-hour period, the system can generate approximately 78.4 volts at a railway station. The project's objectives include generating power from free energy, reducing power generation costs, and promoting cost-effective and cleaner energy solutions. The methodology involves setting up the sensors, designing the circuit, and programming the Arduino to read and process the sensor data. The results show that higher pressure applied to the sensors results in higher voltage and power generation, making the system highly effective in public spaces. The conclusion emphasizes the sustainability and adaptability of piezoelectric sensors for widespread implementation in various environments.The paper presents an innovative power generation system that utilizes piezoelectric sensors to convert footstep pressure into electrical energy. The system, designed for public spaces like bus stands, railway stations, and shopping malls, consists of piezoelectric sensors, an Arduino UNO, an LCD display, a PIC microcontroller, voltage boosters, a battery, an LDR, and a socket for mobile charging. When footsteps apply pressure on the sensors, they generate voltage, which is then converted into electrical power. The system aims to reduce reliance on conventional power sources and conserve natural resources. The maximum voltage generated per step is 22 volts, and the minimum is 1 volt. In a 24-hour period, the system can generate approximately 78.4 volts at a railway station. The project's objectives include generating power from free energy, reducing power generation costs, and promoting cost-effective and cleaner energy solutions. The methodology involves setting up the sensors, designing the circuit, and programming the Arduino to read and process the sensor data. The results show that higher pressure applied to the sensors results in higher voltage and power generation, making the system highly effective in public spaces. The conclusion emphasizes the sustainability and adaptability of piezoelectric sensors for widespread implementation in various environments.