With the development of prototypes which require long development times, the need to build an emulator arises. An emulator is a device that has the same electrical interface and as close as possible characteristics as the end device. It must provide the same electrical responses as the end device. The purpose of an emulator is to allow the customer to prepare for the end device while it is still in the development phase. The thesis presents the development of a drone and vessel jammer control mechanism emulator that emulates the electrical operation of the end device. The emulator has, according to the specification, the appropriate connections for power supply, Ethernet communication, input and output signals and connection for an additional load. The main power connection shall comply with the electrical requirements of the European three-phase voltage system and MIL-STD-1399/300B 'Type I', rated at 440 Vrms, 60 Hz with three-phase connection, without earth and neutral conductor. All connections share protection against electromagnetic and radio-frequency interference and suitability for use in a marine environment. The emulator weighs less than 25 kg and, with a size of 810 x 510 x 170 mm, is suitable to be carried by one person. This requirement has been met by removing all major components that are not strictly necessary to emulate the operation and can be replaced by smaller electrical components with equivalent functionality or simulation. The emulator has implemented communication protocol through which all simulated states are passed, while all emulation is done through the electrical components. For this purpose, the emulator has two Arduino controllers that perform all logic operations and the main part of the emulation. Components that cannot be placed in the emulator are drive systems, position readers and limit switches. These are replaced by electrical switches which have the same normally open and normally closed connections as a limit switch would have. This ensures the same electrical operation as in the end device. All critical signals are additionally checked at the controller and go directly to the signal connector, which is checked by the master device of the end user. Other components that have not been integrated in the emulator have been replaced by a simulation of their operation. This operation is displayed on an integrated touch screen and allows the user to easily operate via on-screen menus. The development of emulator in this project serves as an important milestone in the development of the final device. The development of such device also represents a major added value to the project and an opportunity to demonstrate the performance and capabilities of the final device.