Autonomous mission operations, directly onboard

Autonomous mission operations, directly onboard

orbital_OLIVER enables satellites to plan, decide, and act autonomously by orchestrating payloads, managing resources, and adapting to changing conditions and failures, even when the ground is offline.

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AIKO ONBOARD

DATA PROCESSING

AIKO CUSTOM

APPLICATIONS

CONSTELLATION

MANAGEMENT

THIRD-PARTY
APPLICATIONS

ONBOARD
AUTONOMY

AIKO ONBOARD

DATA PROCESSING

AIKO CUSTOM

APPLICATIONS

CONSTELLATION

MANAGEMENT

THIRD-PARTY
APPLICATIONS

ONBOARD
AUTONOMY

Built for the unexpected

Space missions are becoming more complex, with fewer opportunities for ground intervention. By shifting decision-making onboard, orbital_OLIVER keeps missions productive and resilient, even when unexpected events occur.

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+50%

payload duty cycle

-50%

operator workload

–90%

downlink needs

ONBOARD
AUTONOMY

ANALYSE THE ENVIRONMENT

IDENTIFY THE BEST BEHAVIOUR

UPDATE ACTIONS

ONBOARD
AUTONOMY

ANALYSE THE ENVIRONMENT

IDENTIFY THE BEST BEHAVIOUR

UPDATE ACTIONS

ONBOARD
AUTONOMY

ANALYSE THE ENVIRONMENT

IDENTIFY THE BEST BEHAVIOUR

UPDATE ACTIONS

AIKOSat

0.003, -4.810, 0.001

Sat

0.003, -4.810, 0.001

How onboard intelligence works

Deliver on mission goals rather than predefined schedules; orbital_OLIVER senses, evaluates, replans, and executes in continuous loops, ensuring operations remain optimal and uninterrupted.

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1

Collect

Telemetry, payload status, user goals, anomaly prediction and management.

2

Evaluate

Plan feasibility, resources, timing, visibility, conflicts, and impact on mission return.

3

Replan

Updates mission plan, scheduled operations and acquisitions, maneuvers, downlinks.

4

Execute

Applies actions autonomously and safely.

5

Report

Syncs with ground without breaking autonomy.

What you get
out of the box

What you get out of the box

Goal-based mission planning

Autonomous mission planning based on goals, not scripts, continuously optimising schedules as conditions evolve.

Dynamic tasking & payload orchestration

Dynamic tasking for user or payload requests, with coordinated orchestration across multiple instruments, applications, and onboard data processing pipelines.

Conflict resolution

Automatic resolution of conflicts across power, pointing, thermal, timing, and downlink constraints to ensure operational continuity.

Resource-aware scheduling

Scheduling that accounts for battery, visibility, memory, and duty cycles to maximise mission efficiency.

Autonomous recovery

Autonomous recovery after failures, missed acquisitions, or unexpected events, restoring nominal operations without ground intervention.

Designed to integrate
into any mission architecture

Part of AIKO’s end-to-end autonomy suite, orbital_OLIVER fits seamlessly into existing flight software, payload workflows, and ground operations, without requiring changes to your platform architecture.

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MISSION COMPATIBILITY

Earth Observation
Telecom & TT&C optimisation
Satellite-as-a-Service missions
Multi-instrument platforms
Hosted payload missions
Single satellites or constellations

  • 8%

    duty cycle increase

    1/2

    SUCCESS STORY

    Maximize the instrument usage while preserving battery charging

    The positioning of the payload subsystem on the spacecraft required a specific orientation that was not conducive to power generation. orbital_OLIVER periodically switches the spacecraft to an operational mode, temporarily pausing the generation of payload data to facilitate battery recharging.

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    x

  • -50%

    in power consumed by the TT&C subsystem

    2/2

    SUCCESS STORY

    Autonomous onboard radio reconfiguration in-orbit demonstration

    Excessive usage of onboard power due to the activation of two antennas and two radios. orbital_OLIVER identified the most effective antenna out of four available enboard, optimizing communication with the ground segment.

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    x

  • 8%

    duty cycle increase

    1/2

    SUCCESS STORY

    Maximize the instrument usage while preserving battery charging

    The positioning of the payload subsystem on the spacecraft required a specific orientation that was not conducive to power generation. orbital_OLIVER periodically switches the spacecraft to an operational mode, temporarily pausing the generation of payload data to facilitate battery recharging.

    x

  • -50%

    in power consumed by the TT&C subsystem

    2/2

    SUCCESS STORY

    Autonomous onboard radio reconfiguration in-orbit demonstration

    Excessive usage of onboard power due to the activation of two antennas and two radios. orbital_OLIVER identified the most effective antenna out of four available enboard, optimizing communication with the ground segment.

    DOWNLOAD WHITEPAPER

    x

  • 1/2

    SUCCESS STORY

    Maximize the instrument usage while preserving battery charging

    The positioning of the payload subsystem on the spacecraft required a specific orientation that was not conducive to power generation. orbital_OLIVER periodically switches the spacecraft to an operational mode, temporarily pausing the generation of payload data to facilitate battery recharging.

    8%

    duty cycle increase

    x

  • 2/2

    SUCCESS STORY

    Autonomous onboard radio reconfiguration in-orbit demonstration

    Excessive usage of onboard power due to the activation of two antennas and two radios. orbital_OLIVER identified the most effective antenna out of four available enboard, optimizing communication with the ground segment.

    -50%

    in power consumed by the TT&C subsystem

    x

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AIKO AS A PARTNER

End-to-end delivery

orbital_OLIVER can be provided as a fully integrated solution: AIKO selects and configures the most suitable third-party hardware platforms to ensure reliable onboard execution, optimal performance, and straightforward integration into your mission.

DISCOVER PARTNER

Say goodbye to

missed targets

manual replanning

payload conflicts

service interruptions

Let's get started

CONTACT US

Scalable, flight-ready and user-friendly AI-powered solutions for the space industry.

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TECHNOLOGY

USE CASE

FOR SATELLITE OPERATORS

FOR PAYLOAD & EO TEAMS

FOR MISSION ARCHITECTS & INTEGRATORS

FOR GROUND OPERATIONS

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AIKO S.r.l. - Via dei Mille 22, 10123, Torino, Italy, VAT: 11686290013 | REA: TO1233188
AIKOSPACE S.a.S - Bâtiment NIWA - 33 piste des géants, 31400 Toulouse

© Copyright 2026 All rights reserved

Let's get started

CONTACT US

Scalable, flight-ready and user-friendly AI-powered solutions for the space industry.

WHO

ABOUT

NEWS

WHAT

ALL SOLUTIONS

TECHNOLOGY

USE CASE

FOR SATELLITE OPERATORS

FOR PAYLOAD & EO TEAMS

FOR MISSION ARCHITECTS & INTEGRATORS

FOR GROUND OPERATIONS

CONNECT

CAREERS

PARTNER

NEWSLETTER

PRIVACY POLICY

Subscribe to updates

AIKO S.r.l. - Via dei Mille 22, 10123, Torino, Italy, VAT: 11686290013 | REA: TO1233188
AIKOSPACE S.a.S - Bâtiment NIWA - 33 piste des géants, 31400 Toulouse

© Copyright 2026 All rights reserved

Let's get started

CONTACT US

Scalable, flight-ready and user-friendly AI-powered solutions for the space industry.

WHO

ABOUT

NEWS

WHAT

ALL SOLUTIONS

TECHNOLOGY

USE CASE

FOR SATELLITE OPERATORS

FOR PAYLOAD & EO TEAMS

FOR MISSION ARCHITECTS & INTEGRATORS

FOR GROUND OPERATIONS

CONNECT

CAREERS

PARTNER

NEWSLETTER

PRIVACY POLICY

Subscribe to updates

AIKO S.r.l. - Via dei Mille 22, 10123, Torino, Italy, VAT: 11686290013 | REA: TO1233188
AIKOSPACE S.a.S - Bâtiment NIWA - 33 piste des géants, 31400 Toulouse

© Copyright 2026 All rights reserved