The killer-fly and brain-machine interface.

The hybridization of the microchips and neurons is quite difficult. But the answer for the nutrient problem can be solved by using a bug, what is controlling microchip by using a brain-computer interface. The BMI (Brain Machine Interface) is similar to the BCI. But in that case, the neural tissue connected to the computers operates the interface that allows controlling the physical robot. 

The BMI (Brain-Machine Interface) can turn the bugs into controllers of the bigger robots. The term BMI means a robot can control by the EEG of the living organism. The system delivers the data through the microprocessor and the EEG signals are decoded to signals that control the computer. 

After that, the system gives feedback to the brains of the controller. The system works that the outside operator is delivering a control signal for the brains of the microchip implanted bug.

The system requires the chamber where the bug is, and then the system interacts with it by using the BMI. The data is changed between the bug and its controller and the system that this bug is operating. Sometimes is asked why the bugs that are implanted with microchips cannot control the bigger robots. The BCI/BMI systems can connect the things like dragonflies or dive-bomber killer flies to the drone or even full-scale combat aircraft.  

If the bug is hunting its prey by spitting the poison, that thing can activate things like cannon or other weapons. The thing is that the information that the bug gets must be connected with the hunting behavior. So if the aircraft will put to attack the ground and aerial targets there must be two bugs that are one hunting the flying prey. 

And another hunting for sitting prey. That thing means that the operator who decides to attack against the air targets must select the bug, which attacks against flying prey. And the attack against the ground targets requires selecting the BMI of the bug, which hunts sitting prey from flying. This kind of cyborg system can control miniature multi-purpose drones. 

()https://www.roboticstomorrow.com/article/2018/06/the-world-of-insect-cyborgs/12087

()https://en.wikipedia.org/wiki/Brain%E2%80%93computer_interface

Image:()https://scitechdaily.com/dive-bombing-killer-flies-are-so-fast-over-3g-acceleration-they-lose-steering-control/

The new small-size super-and hypersonic cruise missiles can attack against both airborne and ground-based targets. 

The Spice bomb system (above) uses similar technology with other small size ammunition. So the small-size super and hypersonic missiles are using similar artificial intelligence-based homing systems. And the bodies and engines of those systems are different. 

The cruise system can patrol independently. And it can return to base if the weapon is not needed. But if there is a suitable threat that system can turn to hypersonic flight and try to impact to target. The Spice is the bomb system, but the HCS (Hypersonic Cruise System) can be otherwise similar. But the speed of the projectile is higher. 

The hypersonic missiles and small size hypersonic cruise missiles can attack against both airborne and ground targets. The miniature stealth missile can cruise at high altitudes by using regular miniature jet engines. But during an attack, they might turn to use scramjets. 

When the suitable target is visible, those kamikaze drones will start to dive against those targets from upwards. The new age cruise missiles can destroy the target by using kinetic energy, which means they can impact it and there can be things like microwave transmitters at the nose of that system.