When Canada’s first satellite, Alouette I, was launched in 1962, it carried four STEM antennae; the design was also used on Mercury and Gemini spacecraft that brought the first Americans into space. It will also increase Canadian expertise in the field of optics, atmospheric sciences, artificial intelligence, and Earth observation. Automated manufacturing processes can help to meet this demand, but humans are still required to design the best method to get the work done. To ensure that this equipment can function reliably, accurate force sensors will be used. Satellite systems and equipment are designed to work in harsh space environments and extreme launch conditions. This work supports important activities, such as monitoring the Artic, identifying ships in distress, maintaining Canadian sovereignty in the North, and protecting the border against illegal, unreported, and unregulated fishing and trafficking. $250,000. Canada’s space industry includes more than 100 firms and organizations, contributes 2.3 billion dollars to Canada’s GDP, and employs nearly 10,000 people in well-paying middle-class jobs. The Canadian Space Agency and the University of Calgary, along with other partners, announced that they will develop Canada's contribution to the Solar wind Magnetosphere Ionosphere Link Explorer (SMILE) mission. This project will develop and test a new approach to launching small satellites using a new type of rocket engine designed to make it easier and less expensive to get a small vehicle into orbit. The CSA describes this segment as: “The companies were awarded non-repayable contributions of up to $500,000 for space R&D projects that have a low initial TRL, between TRL 1 and TRL 3. This project will open up a $2 billion greenhouse gas measurement market to Canadian industry. With a simple, story-based user interface, the new Innovation Canada platform can match businesses with the most fitting programs and services in about two minutes. Building on the legacy of Canada’s contributions to Herschel, this work paves the way for an even greater contribution to new far-infrared missions. $249,262. SED Systems, a division of Calian Ltd. – Saskatoon, Saskatchewan How have canadians contributed to the development and use of satellite technology? The growing small satellite market calls for reliable, affordable launch services to get spacecraft to orbit quickly and safely, but the current availability of these services is limited. Business, News, Technology The low-flux, wide-field imaging solution will detect space debris using high-speed measurements of low-light signals and produce high-quality images with low noise levels. When fully operational, NorthStar expects to directly employ 400 highly skilled persons in Canada and create 1,200 indirect jobs.”. Exonetik Inc. – Sherbrooke, Quebec The mission is a collaboration between the European Space Agency (ESA) and the Chinese Academy of Sciences (CAS) to study space weather, the phenomenon that causes the northern lights but can also cause disruptions and damage to technology. $750,000. The project will develop a reliable, low-cost flight computer and software to autonomously control a vehicle during flight, and test the system on the ground. A new satellite called SAR-XL has two independent radars—one that takes wide angle, low-resolution images, and another than produces high-resolution ones. Tags ABB Canada ARTsensing Blue Sky Spectroscopy Bubble Technology Industries Burloak Technologies C6 Launch Systems Canadensys Canadian Space Agency Exonetik GHGSat Good Vibrations Engineering Honeywell Kepler Communications Maya HTT MDA Mission Control Space Services MPB Communications NGC Aerospace Nüvü Camēras Reaction Dynamics SED Systems Space Technology Development Program Square Peg Communications Teledyne Optect UrtheCast Xiphos. Through funding from the Canadian Space Agency (CSA), Canada is contributing the OSIRIS-REx Laser Altimeter (OLA), which will be the most sophisticated lidar (light detection and ranging) system ever flown in space. The system will be evaluated to identify performance improvements like better communication with other systems, lower production costs, and streamlined product designs that will have no moving parts. $101,911. The material will also be tested for other important features like its ability to recover from severe radiation and maintain its shielding ability, manage extreme space temperatures, and function during long missions. $249,000. New fore-optics will improve the way satellites handle elements like stray light sources that cause data errors and calibration problems. From: Innovation, Science and Economic Development Canada. LEO satellites use optical links to communicate data. The model will be tested to ensure it meets defined mechanical and performance goals and inform future 3D printing projects. This project will also test the system’s ability to work with other optical components, which will lower costs and position Canada as a leader in satellite optical communication systems. Today, the Honourable Navdeep Bains, Minister of Innovation, Science and Economic Development, announced an investment of $13 million in NorthStar Earth and Space Inc. One system will automatically calibrate the many images produced by the six satellites. It will design and produce a prototype of a channel bonded modem that gathers under-used bandwidth on satellite modems to produce high output signals to increase communication performance. The project also includes designing and testing cost-effective, space-ready parts like integrated electronic flight systems, solar panels that track the sun, antennas, sensors, and batteries that will be scaled to fit on nanosatellites. The Wide-Angle Fabry-Perot (WAF-P) imaging spectrometer is the main instrument on satellites that are used to measure greenhouse gas emissions from industrial facilities around the world. $999,999. Canadarm, Canada's most famous robotic and technological achievement, made its space debut on the Space Shuttle Columbia (STS-2) on November 13, 1981. Using an existing type of antenna reflector, this project will improve performance, ensure space-readiness, and solve two key design issues. These wide area scans produce low-resolution images, but high-resolution images are needed to identify illegal activities like unregulated fishing. This project will provide three system components to cost-effectively automate this process. By using a similar imaging technique and cooling the telescope, the Space Infrared telescope for Cosmology and Astrophysics (SPICA) will be 100 times more sensitive than Herschel, able to detect objects 10 times further away, and capable of exploring a greater volume of the universe. The miniature platform will be designed to meet the size, weight, and power requirements for commercial use on micro- and nanosatellites. It will use large-scale 3D printers to create a working radio frequency space antenna model. This results in portions of the bandwidth being unattractive to new users, because it is not sufficient for their needs. Improving the instruments that satellites use to detect these emissions will provide decision makers with better data. This material will lead to better protection for astronauts and equipment during space exploration missions, as well as for medical, nuclear, and aerospace workers on Earth. A new set of six Earth-observation satellites will provide a very precise snapshot of most of Earth’s surface on a daily basis so that changes can be tracked over time. The results of this project will position Canada to offer low cost, mass production of compact, telescope fore-optics for Earth observation satellite constellations. $249,560. The results of this project will improve manufacturing efficiency and reduce the high cost associated with one-off parts. This project will provide the ability to detect changes on Earth over time that can be used to identify crop damage, improve environmental monitoring, manage irrigation, and increase crop yields. This project will design a low-cost hardware platform that provides the processing power needed for AI, is less susceptible to the effects of radiation, and is ready for the harsh environment of space. You will not receive a reply. This project will give Canadian industry a competitive edge in the $2 billion greenhouse gas measurement market and provide better alternatives to meet customer needs. $997,342. This project will show how 3D printers can produce low-cost, space ready parts for use in the commercial satellite industry. Search for related information by keyword: Innovation, Science and Economic Development Canada, firstname.lastname@example.org. The lightweight, simplified design concept will improve communications from launch pad to LEO, provide higher data rates, and require less power to operate. Dr. Eric Donovan's scholarship in auroral imaging will be a significant asset to the CSA team, as they strive to forecast geomagnetic storms and protect global navigation satellite systems and communications satellites. The new, lightweight system will use a high-efficiency optical phased array to transmit signals more reliably and be small enough to fit on a single chip. Canada’s space industry includes more than 100 firms and organizations, contributes 2.3 billion dollars to Canada’s GDP, and employs nearly 10,000 people in well-paying middle-class jobs. Used by commercial, government, and space agency customers, the market for low-cost, high-performance satellite technology is growing. Mission Control Space Services Inc. – Ottawa, Ontario $249,991, The CSA describes this segment as: “The companies were awarded non-repayable contributions of up to $100,000 for feasibility studies related to space projects and technologies with strong commercial potential. EMS Technology Canada Ltd., of Sainte-Anne-de-Bellevue, ... (CSA), four Canadian science teams provide important contributions to both satellites, considered to be two of the most ambitious missions seeking to better understand the birth of stars and the dawn of the Universe. This project will develop a data processing framework and software to calibrate the 2,400 sensors that will be used to capture the large amounts of data and high-resolution images. To achieve this, satellite optical terminals will need precision acquisition and tracking capabilities to establish and maintain tightly focused optical communications links. Low Earth Orbit (LEO) satellite constellations currently under development will require the use of high-speed optical inter-satellite links to move vast amounts of data from satellite to satellite. One challenge of the growing space industry is to make high-quality, low production, complex parts quickly that meet customer needs at a low cost. Optical links provide the critical connections that allow data to move between stations on Earth and satellite constellations in space. It will also allow governments and industry to better protect satellites and ground infrastructure such as electrical grids that are critical to serving the everyday needs of Canadians. This project will showcase Canadian innovation and open the market for on-board AI in space, allowing a wide range of AI applications to run directly on a spacecraft. These space R&D projects are expected to last up to three years and produce economic benefits in the next five to 10 years.”. This project will explore new design concepts for a miniaturized spectrometer that can detect smaller concentrations of greenhouse gases while collecting high-resolution images that make the system less vulnerable to alignment issues or camera flaws. Of the $13-million federal investment, $9.5 million comes through the Strategic Innovation Fund, a $1.26-billion program that is helping Canada become a global leader in innovation. The CSA has awarded two contracts: one worth almost $11 million to Honeywell to design the UVI, and the second worth $1.5 million to the University of Calgary to design the UVI Science Operations and Data Centre.