MidSTAR-1is an artificialsatelliteproduced by theUnited States Naval AcademySmall Satellite Program.It was sponsored by theUnited States Department of Defense(DoD)Space Test Program(STP), and was launched on March 9, 2007 at 03:10 UTC, aboard anAtlas Vexpendable launch vehiclefromCape Canaveral Air Force Station.MidSTAR-1 flew along withFalconSat 3,STPSat 1,andCFESatas secondary payloads; the primary payload wasOrbital Express.

MidSTAR-1

MidSTAR-1 Mission (USNA-5)

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MidSTAR-1 Mission Patch

MidSTAR is a general-purpose satellite bus capable of supporting a variety of space missions by easily accommodating a wide range of space experiments and instruments. The integration of the experiments with the satellite bus must be accomplished with minimal changes to the satellite bus design. MidSTAR is intended to be a relatively low-cost, quick response platform accommodating small payloads approved by the DoD Space Experiments Review Board (SERB) and awaiting launch through STP.

MidSTAR is designed for use on theEELV Secondary Payload Adapter(ESPA) Ring developed byAir Force Research Laboratory(AFRL) for placement onDelta IVorAtlas Vexpendable launch vehicles. MidSTAR is a Class D spacecraft, produced at minimum cost with a correspondingly higher technical risk in production and operation. It is intentionally simple in design and rugged in construction, using commercial off-the-shelf “plug-and-play” components to the greatest extent possible. Component development and circuit-board level design are accomplished only when necessary.[citation needed]

MidSTAR-1 is the first implementation of the design. It was commissioned by STP to carry the Internet Communications Satellite (ICSat) Experiment for SSP and theConfigurable Fault Tolerant Processor (CFTP)Experiment forNaval Postgraduate School(NPS). In addition, MidSTAR-1 carries the Nano Chem Sensor Unit (NCSU) for theNational Aeronautics and Space Administration(NASA)Ames Research Center;Eclipse, built by Eclipse Energy Systems, Inc. for NASAGoddard Space Flight Center(GSFC); and the Micro Dosimeter Instrument (MiDN), sponsored by theNational Space Biomedical Research Institute(NSBRI) and built by the USNA Department of Aerospace Engineering. The mission is intended to last two years.[citation needed]

Mission architecture

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The MidSTAR-1 mission includes a single spacecraft under the command and control of a single satellite ground station (SGS) located at theUnited States Naval Academy,Annapolis, Maryland. The ground station forwards downlinked data files to the principal investigators via the Internet. The launch segment for MidSTAR-1 utilized anAtlas Vlaunch vehicle through theSpace Test Program,placing the satellite in acircular orbitat 496 km altitude, 46 degrees inclination.

The satellite uses an uplink at 1.767 GHz with anintermediate frequency(IF) of 435 MHz, and a 2.20226 GHz downlink. By utilizing aGaussianMean Shift Keymodulation,communications with the satellite are achieved at 68.4kbit/s or higher data rate. The satellite also usesopen source softwarebased on theLinuxoperating system.MidSTAR-1 has no attitude control or determination and no active thermal control. The craft has a mass of 118 kg.[1]

One hundred percent success would be the successful launch and operation of the satellite with full support for the two primary experiments for two years. Fifty percent success was the successful launch and operation of the satellite with: Full support of one primary experiment for two years; Full support of both primary experiments for one year; or, partial support of both primary experiments for two years. Thirty-three percent success was successful launch of the satellite and full operation of the satellite bus with partial support of any combination of primary and secondary payloads for any length of time.[citation needed]

Mission log

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9 March 2007: MidSTAR-1 flew as part of theSTP-1mission on a United Launch Alliance Atlas V fromCape CanaveralAir Force Station. Liftoff occurred at 0310UTC;spacecraft separation occurred at 0332 UTC.USNA SGSsuccessfully acquired communications with the spacecraft during the first pass over AnnapolisMDat 0459 UTC. The spacecraft was operating nominally insafe mode.[citation needed]

21 March 2007:CFTPturned on at 2217 UTC to add 6 W continuous to the electrical power system load and thus lessen charging stress on the batteries.

28 March 2007:MiDNturned on at approximately 2400 UTC. Spacecraft stopped responding to all ground commands subsequent to this pass.

4 April 2007: First use offirecode resetof spacecraft at approximately 2130 UTC. This command toggles the reset switch on the MIP-405 processor and reboots the operating system. This reset returned the CFTP and MiDN experiments tooffand cleared all command buffers. At 2324 UTC the spacecraft responded to atransmitter oncommand. Telemetry confirmed that the reboot was successful.

5 April 2007: CFTP and MiDN turned back on.

6 April 2007: Selective download of MiDN files retrieved 71 files of 92byteseach which were delivered to the Principal Investigator (PI). This was the first successful retrieval of science data from the spacecraft. With this milestone, MidSTAR-1 satisfied the criteria of 33% mission success.

26 May 2007: NCSU turned on at approximately 1900Z.

29 May 2007: First data package delivered toNCSUPI. All four experiments are on and delivering data to the PIs.

18 June 2007: NASA press release announces success of NCSU.

5 September 2007: Spacecraft computer froze as a result of unknown influences, most likely radiation-induced upsets. This happened while the spacecraft was in full sun and with the power drains (30 W) on to prevent battery overcharging. Without the computer to cycle the drains off, the spacecraft remained in a continuous negative net power configuration which eventually drained the batteries. When the battery voltage dropped below 8 V, the electronic switches for the drains defaulted to off, returning the spacecraft to positive net power and allowing the batteries to recharge.

7 September 2007: Once the batteries recharged sufficiently, the computer restarted successfully. Restart occurred 48 hours after the initial event. No telemetry from the spacecraft or any experiment is available for that 48-hour period. Telemetry indicates that normal operation resumed, but all experiments were left off pending post-event analysis and the development of a plan to bring them back online.

12 September 2007: CFTP restarted.

21 September 2007: MiDN restarted.

April 2009: Contact with MidSTAR-1 lost. Spacecraft ceased transmitting and failed to respond to ground command. Anomaly attributed to failure of battery packs. MidSTAR-1 declared non-operational. MidSTAR-1 fully supported all onboard experiments for two full years, fulfilling the 100% success criteria.[citation needed]

17 August 2023: the satellite decayed from orbit.[2]

Structure

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The MidSTAR-1 frame is anoctagonalstructure 32.5"along the long axis, including separation system, and 21.2 "x21.2" measured side-to-side in cross-section. The deployment mechanism is mounted on the negative x face. The positive x face is reserved for externally mounted experiments. Of the 38 "along the x-axis allowed in theESPAenvelope, 2-4 "are reserved for the deployment mechanism (15-in motorized lightband manufactured by Planetary Systems, Inc.), and 4-6" are reserved for external experiments. The frame length is 30 ". All eight sides of the spacecraft are covered with solar cells in order to maximize the power available. Eight dipole antennas are mounted on the four faces of the spacecraft which" cut the corners "of the ESPA envelope and are therefore positioned within the ESPA envelope rather than coincident with the envelope surface. The remaining sides are mounted with remove-before-flight eyeholes for lifting and transport during ground support.

MidSTAR-1 has three interior shelves which provide area inside the satellite for mounting of components and payloads. Their locations are determined by the dimensions of the payloads and components. These can be varied in future implementations of the MidSTAR model, if necessary, as long as the structure remains within thecenter of gravityrequirements. The load-bearing structure of the octagon consists of the top and bottom decks, connected at the eight corners by stringers. The side panels of the spacecraft are 1/8 "aluminum panels mounted to the stringers with #10bolts.[citation needed]

Command and Data Handling (C&DH)

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The mission of the Command and Data Handling System (C&DH) is to receive and execute commands; collect, store, and transmit house-keeping data; and support the onboard payloads. The flight computer is designed to control the satellite and manage telemetry and experiment data for a minimum of two years.

The C&DH system consists of a custom-modifiedMIP405-3Xsingle board computer which included (i) 133 MHz PowerPC processor; (ii) 128MBECC;(iii) 4 RS-232 asynchronous serial ports; (iv) 1 Ethernet Port; (v) a PC/104 bus; (vi) a PC/104+ bus; and, (vi) a 202-D384-X Disc on Chip providing 384 MB of secondary storage. The computer board is supported by an ESCC-104 Synchronous Serial Card with 2 synchronous serial ports, and anEMM-8M-XTSerial Expansion Cardwith 8RS-232/422/485 asynchronous serial ports and 8 digital I/O channels. A modified I0485 data acquisition board provides 22analogtelemetrychannels and 32 digital I/O channels.

The decision to use the PowerPC based MIP405 over an x86 based board was based solely on the low power consumption of the board combined with the feature set. The choice was limited to x86, PowerPC, andARMprocessor architectures because of a program decision to use the Linux operating system. The MIP405 integrates Ethernet, serial ports, and Disk-on-Chip interface on a single board while providing 128 MB of ECC memory and a powerful processor for under 2 watts. The closest x86 based system with comparable features found consumed 5 watts of power.[citation needed]

The M-Systems Disk-on-Chip was chosen because it was thede factostandard flash memory harddisk replacement. Flash memory was chosen over a traditional hard disk to increase reliability and reduce power. The 384 MB version was chosen to provide the storage required for the operating system and still maintain adequate margin.

The Diamond Systems Emerald-MM-8 was chosen for the asynchronous serial board based on its innate flexibility with any of the 8 ports capable of being configured as RS-232, RS-422, RS-485.

RMV's IO485 data acquisition and control board was chosen for the distributed telemetry system because of built-in support for daisy chaining and handling a large number of boards. The integrated expandability is fundamental to addressing future telemetry issues in later versions of the MidSTAR line.[citation needed]

The C&DH uses theLinuxoperating system with a 2.4 series kernel. To create an open software architecture theIP protocol stackwas chosen to provide inter process, intra-satellite, and satellite-ground communications. This allowed programs created at different facilities on different hardware to be integrated with minimum difficulty.[citation needed]

All internal and external communications use internet protocols. TCP is used for all internal satellite communications; UDP or MDP is used on the uplink and downlink.[citation needed]

See also

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References

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  1. ^"NASA - NSSDCA - Spacecraft - Details".nssdc.gsfc.nasa.gov.Retrieved2023-11-30.
  2. ^"MIDSTAR 1".N2YO.com.17 August 2023.Retrieved19 August2023.