TECHNOLOGIES
We are pioneering the future of motion through breakthrough engineering in propulsion and control systems.
Spherical Electromagnetic Induction Motor
True freedom of movement, redefined.
This revolutionary motor enables seamless 360° motion in all directions, powered by precision-controlled electromagnetic fields. Compact, efficient, and powerful, the motor eliminates the need for traditional mechanical joints and gimbals. Its spherical architecture and non-contact magnetic actuation allow for silent operation, extreme reliability, and ultra-fast response across any axis.
Inside, a stationary shell houses multiple electromagnetic coils that dynamically generate shifting magnetic fields. These fields induce torque on a suspended inner rotor embedded with magnetic or conductive materials, enabling precise, continuous rotation in pitch, yaw, and roll—without friction or mechanical wear.
The result is a fully omnidirectional motion platform that delivers exceptional agility and control in a compact form factor. With no physical contact between components, the system is highly durable and virtually maintenance-free.
Dynamic Reaction Propulsion System
Harnessing physics to generate thrust—all electric.
The Dynamic Reaction Propulsion System (DRPS) is a revolutionary all-electric propulsion method that generates linear thrust through internal motion, without expelling mass. Leveraging the physics of gyroscopic precession and angular momentum conservation, it introduces a new class of clean, sustainable propulsion.
The system features multiple high-speed gyroscopes mounted symmetrically around the center of mass. By precisely altering the system dynamics—modulating the speed and orientation of the gyroscopes through electromagnetic and mechanical control—the system generates a net reaction force along a chosen direction, typically in the vertical (z-axis) direction.
Because all motion remains internal and is electrically driven, the Dynamic Reaction Propulsion System requires no propellant, produces zero emissions, and functions with exceptional reliability and silence. It offers a compact, reusable alternative to traditional propulsion systems, particularly for environments where fuel-based options are limited or impractical.
Dynamic Moment of Inertia Control System
Changing the rules of motion in real time.
This advanced system enables a spacecraft, vehicle, or mechanical system to dynamically redistribute internal mass and actively control its moment of inertia in real time. By precisely altering how mass is arranged relative to the axis of rotation, it becomes possible to adjust angular acceleration and rotational velocity without external forces—unlocking an entirely new dimension of motion control.
The system operates through a combination of high-speed actuators, sliding masses, and rotating structures, all coordinated by onboard software. When a change in orientation or spin is needed, the system intelligently shifts mass within the structure to either increase or decrease resistance to rotation. This gives the platform the ability to rotate faster, stabilize more efficiently, or conserve energy depending on the operational context.
Such control is especially valuable in mechanical systems that require rapid, precise, and adaptive movement. Whether optimizing energy use, improving stability, or enabling complex motion sequences, the ability to adjust moment of inertia on demand provides a powerful advantage. This level of control enhances overall system responsiveness, efficiency, and performance—opening new possibilities for next-generation motion platforms across multiple industries.