The growth process of herbal Piper Retrofractum Vahl (cabai jamu) requires a sufficient level of water availability with the right time of administration. This situation can be achieved by applying a drip irrigation system because this system can regulate the amount and time of water supply according to the needs of the plant. The drip irrigation system allows farmers to save water use thereby preventing water loss due to evaporation, runoff, and air. In addition, this system will also save time and cost because there is no need to water excessively which can even potentially damage plants. Another advantage of implementing this system is that it produces better plant quality because it can control the humidity around the plant roots constantly. This system can be applied fuzzy method to obtain optimal results. In this case, it is in the form of a simulation to obtain the level of accuracy of the method if it is applied to the plan. Simulation using Tinkercad which is then assembled according to the plan. The electronic circuit is used to test the accuracy of the fuzzy method on the smart drip irrigation system plan. The results of this study indicate that the electronic system is running well as planned, although there is a change in the type of sensor from DHT22 in the simulation to a TMP36 sensor which basically measures the temperature outside the ground or ambient temperature. The two fuzzy logic control methods that are simulated to be applied to the smart drip irrigation plan are very suitable. This is evidenced by the level of conformity reaching 100% so it can be said that the simulation can be applied directly to the smart drip irrigation system plan.

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