As preparations for the flight of the High Altitude Student Platform (HASP) enter their final days, team members Luis and Jimmy took the trip to Fort Sumner, New Mexico to ensure our NEUDOSE Instrument is set up on the platform to specification. Some of their main responsibilities are ensuring the instrument is secure and all the required systems are communicating as planned. Weather permitting, the platform will fly this weekend, sending 12 student payloads to 36km altitude.
This sub-component is responsible for stabilizing and supplying voltage for the extremely sensitive electronics to the rest of the science instrument. By providing stable voltages (in some cases between +/- 1 mV !), we maintain high precision in our scientific measurements.
As anything we do, practice makes perfect. This board is our 2nd full revision, after iterations from initial testing (rev 0) to HASP 2017 (rev 1.0)'s fully assembled and functional model.
With days until our HASP 2018 mission (High Altitude Student Platform), we look back on our accomplishments and in what went right in last year's mission success. Last year, we sent up our first payload to about 34 km altitude. After heavy focus on maintaining the structural integrity of our payload, the mechanical structure successfully survived the landing process. Seeking continuous improvement from last year, we have since refined the electrical systems.
This summer, we will be participating in the HASP (High Altitude Student Platform) 2018. This annual flight program consists of a student-designed platform carrying 12 compact satellites, prototypes, and small experiments to 36km altitude with a balloon. After successfully participating in this event last year, we look forward to putting our hard work to test in preparation for our future mission launch from the ISS.
Preparation for HASP 2018 has been underway the last few months, and with it we have been getting our Printed Circuit Boards (PCBs) manufactured. Here is a preview of our work on the ADS team's board. We will be populating the board with all the required parts in the following weeks. The board will use a combination of an accelerometer, gyroscope, and magnetometer to determine the attitude of the satellite (the orientation, rotation, and velocity).
Luis, Diana, Eric, and Dr. Andrei Hanu attended Bruce Power's license renewal hearing by the Canadian Nuclear Safety Commission. Displaying our hard work and current mission progress, showing how Bruce Power gets involved in the community through their sponsorship of McMaster NEUDOSE. This public involvement helps to link us with the science community to ask us questions and provides a teachable opportunity.
Earlier this month, Hira Nadeem and Liubov Trofimova from the Command & Data Handling team participated and placed 1st in L3 WESCAM's first hackathon, HackWESCAM. In 36 hours, their team WeCycle used a trained neural network in a mobile app to scan and classify items to determine which recycling bin to place them in. An app like this would use geotagging to verify municipal recycling rules are being followed. Congratulations Hira and Liubov!
At 3:23 in the video below is the Daily Planet feature of our team on the Discovery Channel! It is based on the CSA CubeSat program announcement from May 4.
Today, the Canadian Space Agency has announced that as part of their Canadian CubeSat Program (CCP), the McMaster Interdisciplinary Satellite Team's NEUDOSE satellite will be launched from the International Space Station in 2021! A testament to the hard work and dedication of our team leaders and members, the NEUDOSE satellite will be launched and deployed from the ISS by the Canadarm after being (likely) delivered by a SpaceX Falcon 9 rocket.
We are extremely honoured and thankful to the CSA and our sponsors for providing this incredible opportunity. We will do our best to make to make Canada and our national space agency proud!
Check out this featured video by McMaster University!
Check out this latest rendering of the satellite structure, as designed by our mechanical team. The mechanical team's primary goal is to develop the structures that house all of the critical components of the satellite and radiation detector system. They also ensure the satellite is designed to the CubeSat dimensional and structural requirements for space flight. The mechanical structure will be tested as required by the team and launch provider.