Grants and Contributions

This project entitled ""Smart Switch Interface"" is to develop new interface options for COM DEV's switch space product family. The primary objective is to allow the switch products to become CANBus compatible - where CANBus, an already widely accepted communications protocol designed for many electronic products used in aerospace, automotive, maritime, medical and industrial automation equipments, is now being more broadly reviewed for space payload incorporation – therein offering “smart switch” product portfolio enhancement.

Current manufacturing techniques for waveguide switches are difficult, take multiple machines and setups and are challenging to manufacture.

This project entitled ""New Iso-Divider Product"" has the objective: to develop a product that will combine and integrate space worthy Isolators and Power Dividers within the same package, saving space and mass in satellite designs. This product will be used for satellite communication purposes.

This project entitled ""On-Board Autonomous Cross-Cueing of EO Sensor Systems for Maritime Domain Awareness and Tasking Optimization"" has the objective to develop a unique space-borne on-board autonomous cross-cueing and collection tasking system, allowing for optimized high-resolution optical image acquisition yields and downlink capacity utilizations. The operational applications for such a system would be low-latency ship detection and identification reporting, and cloud-free target imaging.

This project entitled ""Dual L and X Band Active Planar Array Antenna for Space-based Radar"" aims to develop the design of a new Synthetic Aperture Radar (SAR) antenna capable of transmitting and receiving on both X and L bands simultaneously with a single aperture. This will include building a prototype subpanel to validate the performance. The targeted application for this technology is for a SAR payload deployed on the International Space Station.

This project entitled ""G-Band - The Next Generation of Cloud Profiling Radars"" focuses on the development of G-band radar technology dedicated to do cloud profiling. Ka- and W-band radars are currently being used to better understand clouds and cloud processes, and their representation in global atmospheric circulation models. There are still gaps in the ability to probe clouds. Using a G-band radar could significantly improve current profiling capabilities in boundary layer clouds, cirrus and mid-level ice clouds, and precipitating snow.

This project entitled ""End-to-End Space-Ground Communication"" will focus on the development and the study of key advancements in satellite on-board processing technology in order to improve the level of integration of an end-to-end communications network. The idea is to provide a fully integrated approach where the utilization of ground and space segments are maximized.

This project entitled ""Geometric Error Source Identification and Quantification (GESIQ)"" has the objective to improve the knowledge of the spacecraft parameters by identifying and quantifying the geometric errors sources in satellite data starting from known geometric errors previously determined using ground control points (GCP). It will allow NGC to have a tool to support customers in the diagnostic of geometric error sources in Earth-observation satellite imagery.

This project entitled ""Autonomous Navigation & Mapping (ANIMA)"" has the objective to develop and validate an innovative navigation and mapping technology to be integrated onboard exploration rover systems. This technological product aims at solving a problem that is often encountered in space and also in many terrestrial applications: to enable the navigation, the mapping and the localization of mobile vehicle systems operating in unknown or poorly known environments where Global Positioning System (GPS) or other absolute navigation infrastructure are not reliable or even available.

This project entitled ""Electron Multiplying Charged Coupled Device (EMCCD) Camera Controller"" aims at advancing the design of the Electron-Multiplying Charge-Coupled Device (EMCCD) camera controller in order to prepare it for future space missions. EMCCD is a digital imaging technology that is capable of detecting single photon events by way of a unique electron multiplying structure built into the sensor. Key technological advancements include reducing power consumption and adapting heat dissipation of the Canadian EMCCD controller. The heat needs to be dissipated even when no air is present, such as is the case in the space environment; while power consumption must be lowered considering the limited availability of resources for most space missions.