Solutions

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Robione Facility Robot is an autonomous mobile solution for factories, warehouses, airports, and logistics sites. It handles loading, transport, stock and baggage movement, towing, and material handling indoors and outdoors — improving efficiency, safety, and sustainability.

R&D

ehicle-agnostic autonomous R&D platforms designed for real-world testing of perception, control, and autonomy technologies.Rapid data collection and validation under operational conditions shorten development cycles and reduce technical risk.

Autonomous operations for yards, ports, and logistics hubs, enabling continuous material movement around the clock.Reduced manual handling, improved safety, and higher operational efficiency without disrupting existing workflows.

Autonomous vehicle operations supporting internal transport and material flow across large industrial facilities.More predictable logistics, higher throughput, and safer working environments through automation of repetitive tasks.

Mining

Autonomous heavy-duty vehicle operations for material transport in harsh and high-risk mining environments.
Improved safety by minimizing human presence in dangerous zones while maintaining operational continuity.

Agriculture

Field-ready autonomous machines supporting precision agriculture and repetitive field operations.
Consistent performance with reduced labor dependency, enabling more efficient and data-driven farming processes.

Usecase

A case study showcasing the development of a turnkey autonomous research platform designed to reduce entry barriers for universities and research institutions transitioning from simulation to real-world autonomy testing.

Context

An academic institution, from Italy, aimed to initiate autonomous vehicle research but faced high entry barriers due to vehicle development costs, system complexity, and required engineering expertise.

Challenge

Starting autonomy research typically requires significant upfront investment in hardware, software integration, and multidisciplinary know-how.
These challenges often delay research activities or prevent institutions from moving beyond simulation-level studies.

Solution

A standard electric golf vehicle was converted into a fully functional autonomous R&D platform within six months.
The resulting system provided a ready-to-use autonomous vehicle capable of supporting real-world software development and experimentation.

Outcome

The institution gained a practical, on-site autonomous test platform to develop, test, and validate autonomy software in real operating conditions. This enabled a fast transition from concept to hands-on research, significantly lowering cost, complexity, and time-to-start for autonomy programs.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project focused on converting an existing, production-ready industrial tractor into an autonomous-capable platform to support the transition toward large-scale deployment.

Challenge

Conventional tractors are not designed for autonomous operation.
Retrofitting an existing vehicle requires reliable drive-by-wire conversion, sensor integration, and vehicle-level validation without redesigning the base platform.

Solution

The tractor was retrofitted with a complete autonomous system, including drive-by-wire control, sensor and electronics integration, and autonomous driving software configuration, enabling electronic control of steering, braking, and propulsion.

Outcome

The autonomous retrofit enabled rapid validation of autonomy on a real production vehicle, reducing technical risk and accelerating readiness for scalable deployment without changes to the original vehicle design.

Context

An industrial stakeholder required a vehicle platform to test autonomous driving capabilities under real operating conditions, without the cost and time burden of full vehicle development.

Challenge

Developing a vehicle capable of both remote control and autonomous operation typically involves high integration effort, long timelines, and significant engineering resources, slowing down field deployment.

Solution

A Toyota Hilux platform was converted into a vehicle integrating remote control (tele-operation) and autonomous navigation capabilities.

The system architecture was designed to support safe remote driving as well as autonomous operation, enabling flexible use across different test scenarios.

Within six months, a fully operational platform was delivered, ready for real-world testing operational trials.

Outcome

The resulting vehicle enabled immediate field trials and software validation under real conditions.

This approach significantly reduced cost, complexity, and time-to-start for real-world autonomous vehicle testing.

Download Datasheet

Usecase

A case study showcasing the development of a turnkey autonomous research platform designed to reduce entry barriers for universities and research institutions transitioning from simulation to real-world autonomy testing.

Context

An academic institution, from Italy, aimed to initiate autonomous vehicle research but faced high entry barriers due to vehicle development costs, system complexity, and required engineering expertise.

Challenge

Starting autonomy research typically requires significant upfront investment in hardware, software integration, and multidisciplinary know-how.
These challenges often delay research activities or prevent institutions from moving beyond simulation-level studies.

Solution

A standard electric golf vehicle was converted into a fully functional autonomous R&D platform within six months.
The resulting system provided a ready-to-use autonomous vehicle capable of supporting real-world software development and experimentation.

Outcome

The institution gained a practical, on-site autonomous test platform to develop, test, and validate autonomy software in real operating conditions. This enabled a fast transition from concept to hands-on research, significantly lowering cost, complexity, and time-to-start for autonomy programs.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project focused on converting an existing, production-ready industrial tractor into an autonomous-capable platform to support the transition toward large-scale deployment.

Challenge

Conventional tractors are not designed for autonomous operation.
Retrofitting an existing vehicle requires reliable drive-by-wire conversion, sensor integration, and vehicle-level validation without redesigning the base platform.

Solution

The tractor was retrofitted with a complete autonomous system, including drive-by-wire control, sensor and electronics integration, and autonomous driving software configuration, enabling electronic control of steering, braking, and propulsion.

Outcome

The autonomous retrofit enabled rapid validation of autonomy on a real production vehicle, reducing technical risk and accelerating readiness for scalable deployment without changes to the original vehicle design.

Context

An industrial stakeholder required a vehicle platform to test autonomous driving capabilities under real operating conditions, without the cost and time burden of full vehicle development.

Challenge

Developing a vehicle capable of both remote control and autonomous operation typically involves high integration effort, long timelines, and significant engineering resources, slowing down field deployment.

Solution

A Toyota Hilux platform was converted into a vehicle integrating remote control (tele-operation) and autonomous navigation capabilities.

The system architecture was designed to support safe remote driving as well as autonomous operation, enabling flexible use across different test scenarios.

Within six months, a fully operational platform was delivered, ready for real-world testing operational trials.

Outcome

The resulting vehicle enabled immediate field trials and software validation under real conditions.

This approach significantly reduced cost, complexity, and time-to-start for real-world autonomous vehicle testing.

Download Datasheet

Usecase

A case study showcasing the development of a turnkey autonomous research platform designed to reduce entry barriers for universities and research institutions transitioning from simulation to real-world autonomy testing.

Context

An academic institution, from Italy, aimed to initiate autonomous vehicle research but faced high entry barriers due to vehicle development costs, system complexity, and required engineering expertise.

Challenge

Starting autonomy research typically requires significant upfront investment in hardware, software integration, and multidisciplinary know-how.
These challenges often delay research activities or prevent institutions from moving beyond simulation-level studies.

Solution

A standard electric golf vehicle was converted into a fully functional autonomous R&D platform within six months.
The resulting system provided a ready-to-use autonomous vehicle capable of supporting real-world software development and experimentation.

Outcome

The institution gained a practical, on-site autonomous test platform to develop, test, and validate autonomy software in real operating conditions. This enabled a fast transition from concept to hands-on research, significantly lowering cost, complexity, and time-to-start for autonomy programs.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project aimed to move autonomous vehicle research beyond simulation by deploying a fully integrated, real-world test platform capable of supporting autonomy software under operational conditions.

The work was carried out within the scope of a project supported by European Union funding.

Challenge

Building a functional autonomous vehicle requires seamless integration of hardware, sensors, and electronic vehicle control.

Hardware integration, sensor deployment, and drive-by-wire conversion are among the most common technical bottlenecks in autonomy projects.

Context

The project focused on converting an existing, production-ready industrial tractor into an autonomous-capable platform to support the transition toward large-scale deployment.

Challenge

Conventional tractors are not designed for autonomous operation.
Retrofitting an existing vehicle requires reliable drive-by-wire conversion, sensor integration, and vehicle-level validation without redesigning the base platform.

Solution

The tractor was retrofitted with a complete autonomous system, including drive-by-wire control, sensor and electronics integration, and autonomous driving software configuration, enabling electronic control of steering, braking, and propulsion.

Outcome

The autonomous retrofit enabled rapid validation of autonomy on a real production vehicle, reducing technical risk and accelerating readiness for scalable deployment without changes to the original vehicle design.

Context

An industrial stakeholder required a vehicle platform to test autonomous driving capabilities under real operating conditions, without the cost and time burden of full vehicle development.

Challenge

Developing a vehicle capable of both remote control and autonomous operation typically involves high integration effort, long timelines, and significant engineering resources, slowing down field deployment.

Solution

A Toyota Hilux platform was converted into a vehicle integrating remote control (tele-operation) and autonomous navigation capabilities.

The system architecture was designed to support safe remote driving as well as autonomous operation, enabling flexible use across different test scenarios.

Within six months, a fully operational platform was delivered, ready for real-world testing operational trials.

Outcome

The resulting vehicle enabled immediate field trials and software validation under real conditions.

This approach significantly reduced cost, complexity, and time-to-start for real-world autonomous vehicle testing.

Download Datasheet

Applications

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01

Automotive Manufacturing

Component and trailer transport between production lines and warehouses.

02

Warehouses & Distribution Centers

Loading bays, cross-docking and yard logistics.

03

Chemical & Process Plants

Safe transport between storage, production and tank areas.

04

Ports &
Terminals

Short-distance container, pallet and equipment movement.

05

Industrial Campuses

Multi-building, multi-zone internal logistics automation.

Applications

Material Handling

Transporting raw materials, components, and finished products between different stages of the production process

Inventory Management

Assisting in stock retrieval, restocking, and organizing inventory within storage facilities.

Assembly Line Feeding

Supplying assembly lines with required components and materials, ensuring a continuous production flow.

App-Controlled Routes

Supplying assembly lines with required components and materials, ensuring a continuous production flow.

App-Controlled Routes

Transporting goods across large warehouses or outdoor storage areas, improving yard efficiency.

Robione Facility Robot is an autonomous mobile solution for factories, warehouses, airports, and logistics sites. It handles loading, transport, stock and baggage movement, towing, and material handling indoors and outdoors — improving efficiency, safety, and sustainability.

Usecases

Autonomous Transition: Enabling Autonomy on Existing Vehicles

Our process is simple, transparent, and built around your existing vehicles.

Autonomous Turnkey Solutions

Vehicle-agnostic autonomous R&D

Learn More

Robioen Usecases

Autonomous operations for yards, ports, and logistics hubs—ensuring 24/7

Learn More

Autonomy Product Usecases

Autonomous vehicle operations for internal transport across large industrial

Learn More

An App-Controlled Solution

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App-Controlled Routes

Based on the sequence of stops specified by the user, robione Facility Robot plans and follows the best route. The user can change the route during the mission.

Efficiency

robione determines the best route between stops in terms of distance and time, and the user can perform remote control and route changes via the GUI. This helps to optimize processes and reduce the costs.

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Time Saving

The GUI determines the most efficient route, helping robione avoid unnecessary stops and delays. This helps to increase operational efficiency and save time.

OUR FOUNDER TEAM

Özkan Köroğlu

Control Engineer

Yunus Emre Elaydın

Embedded Software Engineer

Coşkun Arslan

Software Engineer

Ahmet Can Kara

Hardware Engineer

Hüseyin Baki İnan

Design Engineer

Teleoperation Software

robione Facility Robot's Teleoperation Software helps you:

Save time by managing the robot remotely without physical presence,
Monitor and intervene in real-time to prevent accidents,
Reduce the need for on-site operators and improve task accuracy,
Adapt to unexpected changes in operations with remote adjustments.

Key Features

01. Real-Time Monitoring

Teleoperation Software provides you with live video feed, speed, battery status, and other critical data visualization.

Solutions

Autonomous vehicle operations supporting internal transport and material flow across large industrial facilities.More predictable logistics, higher throughput, and safer working environments through automation of repetitive tasks.

Usecase

Usecase

Usecase

Applications

01

Automotive Manufacturing

02

Warehouses & Distribution Centers

03

Chemical & Process Plants

04

Ports & Terminals

05

Industrial Campuses

Applications

Assembly Line Feeding

Usecases

An App-Controlled Solution

OUR FOUNDER TEAM

Özkan Köroğlu

Yunus Emre Elaydın

Coşkun Arslan

Ahmet Can Kara

Hüseyin Baki İnan

Teleoperation Software

Key Features

01. Real-Time Monitoring

HQ

Ports &
Terminals