ArduSat
Mission type | Citizen science |
---|---|
Operator | NanoSatisfi LLC |
Website | Nanosatisfi.com |
Spacecraft properties | |
Spacecraft type | 1U CubeSat |
Launch mass | 1 kilogram (2.2 lb) |
Start of mission | |
Launch date | 3 August 2013, 19:48:46 | UTC
Rocket | H-IIB |
Launch site | Tanegashima Y2 |
Contractor | JAXA, NanoRacks |
Deployed from | ISS |
Deployment date | 19 November 2013, 12:18:00 | UTC
Orbital parameters | |
Reference system | Geocentric |
Regime | Low Earth |
Epoch | Planned |
ArduSat is an Arduino based nanosatellite, based on the CubeSat standard. It contains a set of Arduino boards and sensors. The general public will be allowed to use these Arduinos and sensors for their own creative purposes while they are in space.[1]
ArduSat is created by NanoSatisfi LLC, an aerospace company which in the words of Phil Plait[2] has "the goal to democratize access to space" and was founded by 4 graduate students from the International Space University in 2012.
ArduSat is the first satellite which will provide such open access to the general public to space.[3] It is one of several crowdfunded satellites launched during the 2010s.[4] Currently the project evolved to the company Because Learning.[5]
Timeline of the project
[edit]Date | Event |
---|---|
June 15, 2012 | Launch of the ArduSat crowdfunding campaign on KickStarter. The goal was to obtain $35000 in funding. |
July 15, 2012 | After 30 days of campaign, the project obtained a total pledge of $106330, from 676 "backers". |
August, 2012 | Design of the ArduSat payload prototype.[6] |
October 27, 2012 | High-altitude test of the ArduSat payload prototype.[7] "The ArduSat payload prototype was carried to 85,000 feet on a high-altitude balloon. During the flight, which took a little over two hours, the payload ran sample programs, ran tests on the sensors, and even snapped some pictures in the upper stratosphere."[8] |
November 20, 2012 | An agreement is signed between NanoSatisfi and NanoRacks for the deployment of the first two small satellites under the ArduSat program via the NASA and the JAXA, one in summer 2013, the other in fall 2013. That makes ArduSat "the first U.S. Commercial Satellite Deployment from the International Space Station"[9] |
December 2012 | Design of "an engineering model of the satellite with flight-hardware equivalent components".[6] |
April 20–21, 2013 | ArduSat is placed as a challenge in NASA's International Space Apps Challenge. The objective of the challenge is to extend the functionality of the ArduSat platform, presented as "an open satellite platform offering on-demand access to Space". 22 projects were submitted to the ArduSat Challenge. |
May 14, 2013 | Release of the first version of the ArduSatSDK on GitHub. This SDK is made available for the general public to propose and develop experiments for the ArduSat platform. |
May–July 2013 | Assembly and testing of the final version of ArduSat-1 and ArduSat-X.[6] |
August 3, 2013 | Launch of the ArduSat-1 and ArduSat-X aboard Kounotori 4 by the H-IIB Launch Vehicle No. 4 from Y2 in Japan, at 19:48:46 UTC[10] |
August 9, 2013 | The Kounotori 4 (HTV-4) is captured by the ISS' robotic arm Canadarm 2 at 11:22 UTC, led towards a ready-to-latch position on the earth-facing port of the Harmony node, and finally installed on its berthing port at 18:38 UTC.[11][12] |
Aug. 30 - Sept. 3, 2013 | Along with the cargo contained in the HTV-4 Pressurized Logistics Carrier (PLC),[13] ArduSat-1 and ArduSat-X are transferred into the ISS.[14] |
Nov. 15, 2013 | Flight Engineer Mike Hopkins installs the Japanese Experiment Module Small Satellite Orbital Deployer on the Multi-Purpose Experiment Platform.[15] |
Nov. 19, 2013 | ArduSat-1 and ArduSat-X are launched from the Kibo Experiment Module's Exposed Facility, (along with the PicoDragon CubeSat). Flight Engineer Koichi Wakata uses the lab's airlock table to pass the Multi-Purpose Experiment Platform outside to Kibo's Exposed Facility. The Japanese robotic arm then unberthes the platform from the Small Fine Arm airlock attach mechanism and maneuvers it into position to release the satellites.[16][17] |
Apr. 15, 2014 | ArduSat X re-entered the atmosphere |
Apr. 16, 2014 | ArduSat 1 re-entered the atmosphere |
Technical features
[edit]ArduSat-1 & ArduSat-X
[edit]The ArduSat project currently consists in two identical satellites: ArduSat-1 and ArduSat-X.
Category | Specifications |
---|---|
General Architecture | 1U CubeSat : the satellites implements the standard 10×10×10 cm basic CubeSat architecture. |
Computing features | Arduino-based : The ArduSat is equipped with 16 processor nodes (ATmega328P) and 1 supervisor node (ATmega2561) (see [18] for features). The processor nodes are dedicated to the computing of the experiments (each on one node), the supervisor uploads the code to the processor nodes. |
Sensors | The Arduino processors may sample data from the following sensors :
|
Coding | The experiments for ArduSat are developed in C/C++ for AVR/Arduino, using the ArduSatSDK. |
Communication | ArduSat is equipped with a half-duplex UHF transceiver, operating in the 435–438 MHz amateur radio satellite band. It implements Forward Error Correction (FEC) and Viterbi coding based on the CCSDS standards.[19]
Both satellites have a Morse beacon (FM-modulated 800 Hz tones) that is transmitted at 20 WPM every two or three minutes on 437.000 MHz. The beacon will be structured in the following format:[20]
|
See also
[edit]References
[edit]- ^ Evan, Ackerman (2012-06-15). "ArduSat: a real satellite mission that you can be a part of". DVICE. Retrieved 2012-06-15.
- ^ Plait, Phil. "KickStart your way to an experiment in space". Discover Magazine. Archived from the original on 2012-06-16. Retrieved 2012-06-15.
- ^ AMSAT. "ArduSat Arduino CubeSat". AMSAT UK. Archived from the original on 2013-02-24. Retrieved 2012-06-15.
- ^ Reyes, Matthew (7 April 2014). "DIY Satellites: Now and Near Future | Make". Make: DIY Projects and Ideas for Makers. Retrieved 2019-01-05.
- ^ "Because Learning - Our Story". Retrieved November 22, 2022.
- ^ a b c These events have been reconstructed from different posts on the ArduSat KickStarter updates wall
- ^ "SparkFun Box in (Near) SPAAAAACE!". SparkFun. Retrieved 2013-08-11.
- ^ "Balloons, TVACs, and Shipping –Oh my!". Retrieved 2013-08-11.
- ^ "ArduSat Selects NanoRacks for ISS Satellite Deployment". SpaceREF. 20 November 2012. Retrieved 2013-08-11.[permanent dead link ]
- ^ "Launch Result of H-II Transfer Vehicle "KOUNOTORI4" (HTV4) by H-IIB Launch Vehicle No. 4". JAXA. Retrieved 2013-08-11.
- ^ "Successful berthing of the H-II Transfer Vehicle "KOUNOTORI 4" (HTV4) to the International Space Station (ISS)". JAXA. Retrieved 2013-08-11.
- ^ "Japanese Cargo Craft Captured, Berthed to Station". NASA. Retrieved 2013-08-11.
- ^ "HTV-4 Mission payload description". JAXA. Retrieved 2013-09-04.
- ^ "HTV-4 Mission schedule". JAXA. Retrieved 2013-09-04.
- ^ "Expedition 38 Wraps Up First Week on Station". NASA. Retrieved 2013-11-19.
- ^ "Expedition 38 Prepares Japanese Lab for Cubesat Deployment". NASA. Retrieved 2013-11-19.
- ^ "Crew Deploys Tiny Satellites and Tests Spacesuit Repairs". NASA. Retrieved 2013-11-20.
- ^ "ArduSat Payload Processor Module". freetronics. 2013.
- ^ "ArduSat Arduino CubeSat Technical Details". AMSat-UK. 20 June 2012. Retrieved 2013-08-11.
- ^ "Help Track Ardusat-1/X!". NanoSatisfi. Archived from the original on 2013-12-08. Retrieved 2013-11-19.