This study proposes a crop-state-based feedback control algorithm that utilizes crop physiological responses as direct feedback signals to address energy waste and control inefficiency issues in vertical farms. Physiological indicators such as leaf temperature, leaf color, and NDVI were collected in real-time from RGB, thermal imaging, and spectral sensors. These were fused with environmental sensor data (temperature, humidity, CO₂, illuminance) to determine the physiological state of the crops. The control algorithm intelligently operated equipment such as lighting, heating/cooling, and irrigation based on the results classified into normal, stress, light saturation, and stress+light saturation states. Results from the pilot environment at Suncheon National University's vertical farm demonstrated that the proposed algorithm achieved energy savings of 27.8% for LED lighting, 19.4% for heating/cooling, and 31.2% for irrigation pumps compared to existing threshold-based control. Overall power consumption decreased by an average of 23.6%. Additionally, leaf temperature decreased by an average of 1.2°C, and NDVI values improved, enhancing crop photosynthetic efficiency and growth stability. This study is significant in expanding the control paradigm of vertical farms from an environment-centric approach to a crop-condition-based feedback control structure. Future work is expected to advance this into a sustainable smart vertical farm model capable of autonomous adaptation across diverse crops and environmental conditions by applying reinforcement learning-based control models and multi-feedback loop structures.