Optimal smart contract for autonomous greenhouse environment based on IoT blockchain network in agriculture

•The proposed platform aims to develop an optimal smart contract integrated with prediction, optimization, and control for operating actuator state in a greenhouse environment to boost the agriculture product production with less energy consumption.•The main objective of the proposed platform is to achieve a balance between energy consumption and desired parameters of atmospheric conditions in greenhouse farming, such as temperature, humidity and level of Co2.•The proposed framework fulfils the demands of the practical IoT network that encompasses a bulk of greenhouse IoT sensors connected to a single blockchain via different constrained networks. The Internet of Things (IoT) has been widely adopted in many smart applications such as smart cities, healthcare, smart farms, industry etc. In recent few years, the greenhouse industry has earned significant consideration from the agriculture community due to its ability to produce fresh agricultural products with immense growth and production rate. However, labour and energy consumption costs increase the production cost of the greenhouse by 40–50% approximately. Moreover, the security and authenticity of agriculture data, particularly for yield monitoring and analysis, is also a challenging issue in current greenhouse systems.The greenhouse require optimal parameter settings with controlled environment to produce increase food production. Therefore, slight advancement can bring remarkable improvements concerning the increase in production with reduced overall cost. In this work, we contributed blockchain enabled optimization approach for greenhouse system. The proposed approach works in three steps to provide optimal greenhouse environment that are; prediction, optimization, and finally controlling. Initially, the Kalman filter algorithm is employed for predicting the greenhouse sensor data. In next step, the optimal parameters are computed for the indoor greenhouse environment. Finally, the optimized parameters are utilized by the control module to operate and regulate the actuator’s state to meet the desired settings in the indoor environment. To evaluate the performance of our proposed greenhouse system, we have developed an emulation tool. The proposed system has been investigated and compared against baseline approach concerning production rate and energy consumption. The obtained results reveal that the proposed optimization approach has improved the energy consumption by 19% against the prediction based