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Delft, Netherlands
51-100 Employees
2006
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Featured
ISIS CubeSat Development Platform
... The ISIS CubeSat Development Platform is based on the previous ISISPACE successful missions including CubeSat subsystems with high heritage. ...
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Featured
LINE 1 Overview | Cervos Space | Nanosatellites | CubeSats | Design future of space
... LINE 1 Overview | Cervos Space | Nanosatellites | CubeSats | Design future of ...
Rome, Italy
11-50 Employees
The IMT 6U Platform is a flexible solution that meets the performance required for a wide range of applications. Our platform meets a wide range of mission typologies: Science, Earth observation, Technology demonstration. IMT is a private SME, founded in 1991 and active in the Space sector on two main types of activities:.
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Featured
Cubesat 6U Platform
... HORTA CubeSat 6U (Regione Lazio Program) ...
Stellenbosch Local Municipality, South Africa
51-100 Employees
2020
We are unique in our ability to design and deploy world-class imaging systems using decades of experience in leading-edge camera and satellite technology. Earth Observation plays a crucial role in our mission as it gathers information about the planet. Our manufacturing facility in Stellenbosch features large clean rooms as well as comprehensive test and development facilities. Our aim is that our facilities will allow for the production of up to 48 satellites (200 kg) annually, enabling us to compete with the most advanced agile aerospace companies in the world. Dragonfly Aerospace’s vision is to provide decision makers with accurate and accessible data to inform their choices. Dragonfly Aerospace is a leader in high-performance imaging satellites and payloads. Equipped with state-of-the-art Dragonfly imaging technology, EOS SAT-1 is the world’s first commercial agri-focused satellite and was launched into orbit on 3 January 2023. As the first of a seven-satellite constellation in low Earth orbit (LEO), EOS SAT-1 is designed to support the implementation of sustainable agriculture methods and forestland monitoring with high-quality data and analysis.
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Featured
Reliable CubeSat Cameras for Superior Earth Observation
... We create smallest optical payloads for CubeSats. Our reliable earth observation CubeSat camera systems are a revolutionary solution for obtaining high-qualityphotos from space. ...
Spain
11-50 Employees
The Xatcobeo project was a part of launching the Vega rocket in Kourou, specifically from the Guiana Space Centre. With additional power, Xatcobeo’s life expectancy will be extended, and the spacecraft’s performance will be improved. XaTcobeo’s CubeSat downlink transmissions used UHF bands of 437 MHz, Manchester pulses (SP-L), and a data rate of 1.2 kbit/s or only 12.5% of the system’s maximum capability. The first Spanish CubeSat, XaTcobeo, was among the secondary payloads. The Xatcobeo mission might have ended in 2014, but it doesn’t mean that the interest in satellite missions died with it. The Xatcobeo mission used commercial-of-the-shelf (COTS) technologies to perform complex functionalities while keeping the structures simple and low-cost. One of those selected for the launch is a university project originally dubbed Dieste. Retegal, a corporation owned by the Galician government, supported this non-earth observing mission.
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The Xatcobeo Project: A Sound Basis for Future CubeSat Missions
... The Xatcobeo Project: A Sound Basis for Future CubeSat ...
Monte Grande, Argentina
1-10 Employees
2019
Implementación de soluciones analíticas en tiempo real, proporcionar visualizaciones interactivas, capacidades de inteligencia empresarial, algoritmos predictivos y machine learning para ejecutar simulaciones de datos y darle el rumbo indicado a su negocio. Convertimos su página web en una aplicación móvil, android, IOS. Desarrollo de circuitos y placas a medida de nuestra clientela. Sincronización inteligente de sus dispositivos bajo plataforma única de distribución. Máquinas y sistemas de producción robustos en consonancia con plantel preexistente.
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Featured
Subsistema de control térmico para cubesat
... Subsistema de control térmico para cubesat ...
Budapest, Hungary
1-10 Employees
2020
We are building a tool to overcome this challenge and make these processes much easier for you during the development lifecycle. We are developing an analysis tool that is an easy-to-use and easy-to-learn cloud-based application where you can start to build your nanosatellite mission within minutes. We provide a drag and drop tool to layout the CubeSat wings, solar arrays and solar cells placement. We are passionate to help our customers in this huge step forward. We are also open to provide top expertise in the field of mission planning and analysis. Nanosatellite mission planning and analysis are time-consuming and challenging processes. Planning a space mission requires extensive knowledge in various engineering and scientific fields which for an organisation interested in creating a space application is enormous and unnecessary overhead. We assist the space application creators to focus on their main areas to achieve efficient mission planning..
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Featured
Mission design | Ephemersys
... Mission design, cubesat and spacecraft simulation from ...
Nigrán, Spain
1-10 Employees
2020
UARX Space founders, Yanina Hallak and Andrés Villa, walked a long way in the Space industry before starting the company. They participated in multiple CubeSats missions from the University that co-creates the standard. After that, Yanina & Andrés decided to create UARX, a family-owned business, to design and build spacecraft that put CubeSats and SmallSat into their desired orbits, from LEO to the Moon and deep space. The information normally does not identify you, but it help us to provide you a more personalized experience.
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The most advanced 12U CubeSat deployer
... The most advanced 12U CubeSat ...
Toulouse, France
11-50 Employees
Le Club CubeSat est un club technique de l’ISAE-Supaéro composé d’ étudiants originaires des cycles ingénieur et master.
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Club CubeSat – Club étudiant Nano-Satellites à l'ISAE-SUPAERO
... Club CubeSat – Club étudiant Nano-Satellites à l'ISAE- ...
Mumbai, India
11-50 Employees
2017
We are a Space Safety and Logistics Company, using technology to save the Trillion $ Space industry from Debris Pollution in Space. To prevent this, we are developing an Agile, Safe, Efficient and Affordable Green Propulsion System with a new fuel, engine and catalyst for the engine to avoid satellite collision in space and prevent Debris Pollution. We believe Space has the power to solve multiple problems on the earth and help 7B people directly or indirectly. Pratham is an Indian ionospheric research satellite whose primary mission is to count electrons in the Earth's ionosphere. Ashtesh is a visionary of revolutionary space transportation. We believe that the problems of Earth can be solved using Space.
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Products | Manastu Space - Green Propulsion System and Debris Avoidance
... Collision Avoidance System for Cubesat ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for CubeSat
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 77 |
| Amount of suitable service providers | 54 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 2006 |
| Youngest suiting company | 2020 |
A CubeSat is a type of miniaturized satellite for space research that is made up of multiple cubic units of 10×10×10 centimeters, weighing no more than 1.33 kilograms per unit. This innovative design standard was developed in the early 2000s to facilitate access to space for small-scale research projects and educational purposes. CubeSats have dramatically transformed the landscape of space exploration and satellite technology by offering a cost-effective, accessible platform for conducting scientific experiments, Earth observation, and technology demonstration in space. Unlike traditional satellites, which can be costly and require years of development, CubeSats allow universities, research institutions, and even high schools to design, build, and launch their own satellites at a fraction of the cost and time. Furthermore, CubeSats can be launched as secondary payloads, hitching a ride with larger missions, which further reduces launch costs. Their small size and standardized design also enable rapid iteration and development of space technologies, fostering innovation and expanding opportunities for scientific research beyond Earth's atmosphere. The impact of CubeSats on the field of space research is profound, as they democratize access to space, encourage international collaboration, and stimulate advancements in satellite technology and space science.
1. Cost-Effectiveness
CubeSats are significantly less expensive to design, build, and launch compared to traditional satellites. Their standardized dimensions and use of off-the-shelf components keep manufacturing and testing costs low, enabling more organizations to participate in space missions.
2. Innovation and Flexibility
The compact size and reduced cost of CubeSats encourage innovation, allowing researchers and companies to test new technologies in space more frequently. This adaptability supports rapid iteration and development cycles, accelerating technological advancements.
3. Access to Space
CubeSats offer a more accessible entry point into space exploration for educational institutions, small companies, and developing countries. This democratization of space allows a broader range of participants to conduct scientific research and commercial activities beyond Earth's atmosphere.
4. Deployment and Scalability
Due to their small size, CubeSats can be deployed as secondary payloads, hitchhiking on launches with larger satellites, which leads to more frequent and cost-effective launch opportunities. Additionally, CubeSats can be scaled up by deploying constellations to increase coverage and data collection capabilities.
1. Technical Expertise and Reputation
Ensure the supplier has a solid track record of successful CubeSat projects, indicating their capability and reliability in the field.
2. Cost-effectiveness
Evaluate if the supplier offers competitive pricing without compromising on the quality and performance of the CubeSat components.
3. Customization Capabilities
The ability to tailor CubeSat components to specific mission requirements is crucial for the success of your project.
4. Compliance with Standards
Check that the supplier adheres to international CubeSat and space industry standards, ensuring the safety and compatibility of their products.
5. Support and Maintenance
Assess the level of post-sale support and maintenance services offered, as ongoing technical support can be vital for mission success.
CubeSats have revolutionized the satellite industry with their compact size and lower cost, offering a range of B2B applications across various sectors. In the telecommunications industry, CubeSats are pivotal for creating decentralized networks. These small satellites enable businesses to deploy their communication infrastructure, ensuring secure and reliable data transmission even in remote areas. This capability is crucial for companies operating in locations where traditional communication networks are unreliable or non-existent. In the field of earth observation and environmental monitoring, CubeSats provide invaluable data for agriculture, mining, and climate studies. Agricultural businesses utilize CubeSat-derived data for precision farming, optimizing irrigation, and monitoring crop health, significantly improving yield and resource efficiency. Mining companies leverage them for surveying and planning, reducing environmental impact and operational costs. Additionally, CubeSats play a critical role in tracking climate change, offering insights that help industries adapt their strategies to environmental challenges. The maritime and logistics sectors benefit from CubeSats through enhanced tracking and monitoring of shipments and assets. These satellites offer global coverage, enabling real-time location tracking, weather condition updates, and route optimization. This information helps reduce operational risks, improves supply chain efficiency, and enhances overall safety at sea. CubeSats also serve the defense and security sector by providing cost-effective solutions for surveillance, reconnaissance, and communication. Their deployment can enhance situational awareness, support disaster response efforts, and bolster national security measures, offering a strategic advantage to government and private entities alike. Overall, CubeSats' versatility and affordability make them a game-changer for businesses seeking to leverage space technology for competitive advantage, operational improvements, and sustainability initiatives across industries.
CubeSats, as of the latest evaluations, are widely recognized to be at a high Technology Readiness Level (TRL), typically classified at level 9. This classification signifies that CubeSats are not only extensively tested but are also fully operational in their actual environment, which in this case is space. The primary factor contributing to their high TRL is the successful deployment and operation of numerous CubeSat missions by various governmental, commercial, and educational entities around the globe. These miniature satellites have demonstrated their utility in a wide array of applications, from scientific research and weather observation to defense and educational purposes. The compact, standardized design of CubeSats has facilitated cost-effective access to space, effectively lowering the barrier for space exploration and utilization. Technical advancements in miniaturization and communication technologies have further augmented their capabilities, allowing these satellites to perform complex tasks previously reserved for larger, more expensive satellites. Their modular design enables rapid development and deployment, significantly reducing the time from concept to orbit. As CubeSats continue to evolve with advancements in propulsion, power efficiency, and payload capacity, their high TRL reflects not only their current operational success but also their potential for future innovation and application in space exploration and beyond.
In the Short-Term, CubeSats are poised to become more accessible and cost-effective, thanks to advancements in miniaturization and manufacturing technologies. The development of standardized deployment mechanisms and off-the-shelf components will allow for quicker and cheaper satellite launches, enabling a wider range of institutions and businesses to participate in space missions. This democratization of space technology will spur innovation in Earth observation, telecommunications, and scientific research. Looking at the Mid-Term outlook, CubeSats are expected to feature enhanced propulsion systems, allowing for more precise maneuvering and longer mission lifespans. Breakthroughs in solar panel efficiency and battery technology will provide these miniaturized satellites with greater power, supporting more complex instrumentation and data collection capabilities. Additionally, the integration of artificial intelligence and machine learning algorithms will enable CubeSats to autonomously process data in space, reducing the latency in decision-making processes and data analysis. Over the Long-Term, the evolution of CubeSats is likely to be characterized by the development of inter-satellite communication networks, forming autonomous, self-organizing constellations. These networks will revolutionize global communication systems, providing real-time, worldwide coverage. The advent of advanced materials and shielding technologies will also enhance the durability of CubeSats, allowing them to withstand harsh space environments for extended periods. This will open new frontiers in deep space exploration and in-situ resource utilization, marking a significant leap forward in our capabilities to explore and utilize space.
