SB SPACE @ ARL $ARLS003
ARLS003 Ham Radio Satellites to Deploy from ISS

ZCZC AS03
QST de W1AW
Space Bulletin 003 ARLS003
From ARRL Headquarters
Newington, CT June 14, 2019
To all radio amateurs

SB SPACE ARL ARLS003
ARLS003 Ham Radio Satellites to Deploy from ISS

Three BIRDS-3 satellites with Amateur Radio payloads are scheduled
to be deployed from the International Space Station on Monday, June
17. The BIRDS-3 constellation includes CubeSats from three
countries: They are Nepal's first satellite, NepaliSat-1; Uguisu
from Japan, and Sri Lanka's first satellite, Raavana-1.

The primary mission of the BIRDS constellation is to provide
ciphered short messages via its 435.375 MHz beacon, giving the
opportunity for the Amateur Radio community to decipher the messages
using a publicly available key on the BIRDS-3 website at, http://birds3.birds-project.com/document/amateur/ .

Operators able to successfully decipher the message will be
recognized on the BIRDS-3 website and receive a BIRDS-3 QSL card.

Live streaming of the deployment starts at 0835 UTC at, https://www.youtube.com/watch?v=rrw3cMw10nQ . An April 11 Cygnus
resupply mission to the ISS delivered the three BIRDS-3 CubeSats and
three other CubeSats.
NNNN
/EX
--- SBBSecho 3.07-Win32
* Origin: The Thunderbolt BBS - tbolt.synchro.net (454:1/33)

SB SPACE @ ARL $ARLS004
ARLS004 LightSail 2 Launches, Will Transmit CW Beacon

ZCZC AS04
QST de W1AW
Space Bulletin 004 ARLS004
From ARRL Headquarters
Newington, CT June 27, 2019
To all radio amateurs

SB SPACE ARL ARLS004
ARLS004 LightSail 2 Launches, Will Transmit CW Beacon

The Planetary Society's LightSail 2 CubeSat, launched on June 25,
will transmit Morse code from space. LightSail is a citizen-funded
project to send a small spacecraft, propelled solely by sunlight,
into Earth's orbit. The innovative satellite is due to be deployed
on July 2 from Prox-1, a Georgia Tech student-built spacecraft the
size of a small washing machine. Once deployed, LightSail 2 will
automatically transmit a beacon packet every few seconds, which can
be decoded into 238 lines of text telemetry describing the
spacecraft's health and status, including everything from battery
status to solar sail deployment motor state. Every 45 seconds, the
spacecraft will transmit "LS2" on the spacecraft's frequency of
437.025 MHz, within the Amateur Radio 70-centimeter band.

Further details can be found online at, http://www.planetary.org/explore/projects/lightsail-solar-sailing/ .

LightSail 2 lifted off from Kennedy Space Center, Florida, carried
by the SpaceX triple-booster Falcon Heavy rocket. The launcher also
carried aloft two dozen spacecraft for the US Air Force STP-2
mission. Launch had been set to occur late on June 24, but SpaceX
delayed the liftoff to make additional ground system checks.

"During its ride to orbit, LightSail 2 was tucked safely inside its
Prox-1 carrier spacecraft," The Planetary Society said post-launch.
"The Falcon Heavy upper stage's payload stack released Prox-1 about
an hour and 20 minutes after liftoff, at an altitude of roughly 720
kilometers (446 miles). Prox-1 will house LightSail 2 for one week,
allowing time for other vehicles released into the same orbit to
drift apart so each can be identified individually."

Bruce Betts, Planetary Society chief scientist and LightSail 2
program manager, said, "After years of hard work, we are ecstatic
with the launch and looking forward to doing some solar sailing."
Some 500 Planetary Society members and supporters were on hand at
the Kennedy Space Center Apollo-Saturn V Center to watch their
crowdfunded spacecraft take flight.

LightSail 2 team members will soon converge at Cal Poly San Luis
Obispo in California, where the spacecraft's mission control is
located. Once LightSail 2 is released from Prox-1, the team will
spend several days checking out its systems before commanding its
dual-sided solar panels to deploy. Following that, the spacecraft's
solar sails will be deployed in approximately 2 weeks.

Two US Naval Academy student-built satellites carrying Amateur Radio
payloads were on the launch. BRICSat-2 (call sign USNAP1) will
function as a 1.2/9.6 k APRS digipeater on 145.825 MHz. Telemetry
will be transmitted on 437.975 MHz. PSAT-2 also will operate on
145.825 MHz with APRS to voice and DTMF to voice/APRS, and it will
carry a 28.120 MHz up/435.350 MHz down PSK31 transponder. An SSTV
camera will transmit on the same downlink.
NNNN
/EX
--- SBBSecho 3.07-Win32
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SB SPACE @ ARL $ARLS005
ARLS005 China to Launch CAMSAT CAS-6 Satellite on December 20

ZCZC AS05
QST de W1AW
Space Bulletin 005 ARLS005
From ARRL Headquarters
Newington, CT December 19, 2019
To all radio amateurs

SB SPACE ARL ARLS005
ARLS005 China to Launch CAMSAT CAS-6 Satellite on December 20

The CAMSAT CAS-6 amateur radio payload is set for launch on Friday,
December 20, at 0321 UTC from the Taiyuan Satellite Launch Center,
piggybacked on a TIANQIN-1 technology test satellite, using a CZ-4B
launch vehicle. The primary launch payload is the China-Brazil Earth
Resources Satellite CBERS-4A.

The microsatellite, to be known as CAS-6/TIANQIN-1, will be placed
into a Sun-synchronous orbit at an apogee of 390 miles. It will
operate on VHF and UHF using the call sign BJ1SO. The telemetry
beacon is on 145.910 MHz, while telemetry (4k9 baud GMSK) will be
transmitted on 145.890 MHz. CAS-6 will carry a U/V linear
transponder, with a downlink of 145.925, 20 kHz passband (inverted),
and an uplink of 435.280 MHz.

CAMSAT has provided CAS-6 Satellite Digital Telemetry Description
and CW Telemetry Beacon Encoding Format documents available in PDF
format at,
http://www.arrl.org/files/media/News/ CAS-6%20Satellites%20Digital%20Telemetry%20Description.pdf

(above URL all on one line)

and

http://www.arrl.org/files/media/News/ CAS-6%20CW%20Telemetry%20Encoding%20Format.pdf .

(above URL all on one line)
NNNN
/EX
--- SBBSecho 3.10-Win32
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SB SPACE @ ARL $ARLS006
ARLS006 Commemorative ARISS Slow-Scan TV Transmissions Set

ZCZC AS06
QST de W1AW
Space Bulletin 006 ARLS006
From ARRL Headquarters
Newington, CT December 26, 2019
To all radio amateurs

SB SPACE ARL ARLS006
ARLS006 Commemorative ARISS Slow-Scan TV Transmissions Set

Amateur Radio on the International Space Station (ARISS) will
support slow-scan television (SSTV) transmissions worldwide in
memory of cosmonauts Alexei Leonov, Valery Bykovsky, and Sigmund
Jaehn. Transmissions are scheduled to start at 1100 UTC on December
28 and continuing until 1820 on January 1, 2020. Transmissions will
take place on 145.800 MHz and in the PD 120 format, using the call
sign RS0ISS. The Polish ARISS Team has prepared an award for
participants in the SSTV experiment.
NNNN
/EX
--- SBBSecho 3.10-Win32
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SB SPACE @ ARL $ARLS001
ARLS001 HuskySat-1 with VHF/UHF Linear Transponder Set to Deploy
Soon

ZCZC AS01
QST de W1AW
Space Bulletin 001 ARLS001
From ARRL Headquarters
Newington, CT January 28, 2020
To all radio amateurs

SB SPACE ARL ARLS001
ARLS001 HuskySat-1 with VHF/UHF Linear Transponder Set to Deploy
Soon

The University of Washington's HuskySat-1 3U CubeSat, launched
November 2, 2019, is set to deploy on January 31 after the vehicle
that carried it to the International Space Station undocks.

HuskySat-1 has remained stowed aboard a Northrop Grumman Cygnus
supply vehicle. Within 24 hours after Cygnus' departure from the
ISS, HuskySat-1 and SwampSat 2 will be deployed into orbit. After
deployment, HuskySat-1's 1200 bps BPSK beacon on 435.800 MHz should
be active and decodable with the latest release of AMSAT's FoxTelem
software. HuskySat-1 is expected to carry out its primary mission
before being turned over to AMSAT for amateur radio operation.

The FoxTelem software is available at, https://www.amsat.org/tlm/leaderboard.php?id=0&db=FOXDB .

HuskySat-1 features a 30 kHz wide V/U linear transponder for SSB and
CW. The uplink passband will be 145.910 - 145.940 MHz LSB/CW. The
downlink passband will be 435.840 - 435.810 MHz USB/CW (inverting).
Telemetry will be transmitted on 435.800 MHz, 1k2 bps BPSK with an
experimental downlink at 24.049 GHz.

The "Fox-in-a-Box" FoxTelem software has been updated for HuskySat-1
operation and is available at its download website at, http://burnsfisher.com/AMSAT/FoxInABox/ .

The new release now contains the SD card image,
FIAB-distro8-V1.08w.zip. This file, when unzipped and written to a
16 GB SD card will provide the latest software for FoxTelem and will
run on a Raspberry Pi 4. The 1.08 versions can switch bands between
listening on VHF and UHF, based on which Fox and Husky satellites
are overhead at the time.

The linear transponder and telemetry system carried aboard AMSAT's
Fox-1E was designed for use in different CubeSats merely by adding
an interface adapter for connection to the host bus. Noting the
prevalence of CubeSats built and launched by universities and other organizations, AMSAT adopted a goal of "amateur radio in every
CubeSat." Interested CubeSat programs wanting to fly an amateur
radio payload may partner with AMSAT to carry one of these modules
on their spacecraft.

By providing amateur radio capability, the CubeSat program gets a
worldwide ground station network to receive telemetry and experiment
data, while the amateur radio community gets a transponder to use in
orbit. Additional information is posted on the University of
Washington Husky Satellite Lab site.
NNNN
/EX
--- SBBSecho 3.10-Win32
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SB SPACE @ ARL $ARLS002
ARLS002 AMSAT Cites Need for Adequate Spectrum in Opposing Deletion
of 3.4 GHz Band

ZCZC AS02
QST de W1AW
Space Bulletin 002 ARLS002
From ARRL Headquarters
Newington, CT February 27, 2020
To all radio amateurs

SB SPACE ARL ARLS002
ARLS002 AMSAT Cites Need for Adequate Spectrum in Opposing Deletion
of 3.4 GHz Band

AMSAT has commented on the FCC Notice of Proposed Rulemaking (NPRM)
in WT Docket 19-348 that proposes to delete the 3.3 - 3.5 GHz (9
centimeter) amateur band and relocate incumbent non-federal
operations. The band includes the 3.40 - 3.41 GHz Amateur Satellite
service allocation. In its remarks, AMSAT said it opposes deletion
of the allocation and stressed the necessity of having adequate
microwave spectrum available for future amateur satellite projects,
including AMSAT's GOLF program and the Lunar Gateway. AMSAT
acknowledged that the 3.4 GHz Amateur Satellite service allocation
is not currently used by any amateur satellites and that it is
unsuitable for worldwide communication because it is not available
in ITU Region 1. AMSAT said a number of potential future uses for
the band remain, however, as worldwide usage of other available
allocations increases.

AMSAT's comments can be found online in PDF format at, https://www.amsat.org/wordpress/wp-content/uploads/2020/02/ Comments-of-Radio-Amateur-Satellite-Corporation-WT-Docket-No-19-348.pdf
.

(above URL all on one line)

"These potential uses include a future amateur satellite in
geostationary orbit above the Americas," AMSAT said, explaining that
the segment could support uplink or downlink frequencies for such a
spacecraft without potential interference to worldwide activities
involving space stations in high-earth or lunar orbit. The
most-desirable allocations for use as uplinks are between 2.4 GHz
and 5.67 GHz - 80 MHz in all, AMSAT told the FCC. "As many of the
proposed uses include amateur television and high-speed data
transmission with satellites in high-earth orbit or lunar orbit,
these allocations may quickly become inadequate," AMSAT said.

AMSAT told the FCC the 3.40 - 3.41 GHz allocation could be utilized
as a command channel or secondary data downlink for AMSAT ground
stations in ITU Region 2 without interfering with the primary
communications on the other allocations or other satellites
utilizing those segments. AMSAT said several non-amateur satellites
use the broader 3.3 - 3.5 GHz amateur allocation, which also sees
wide use for amateur radio mesh networking, EME communications, and
contesting.

"The amateur satellite service continues to provide immense value to
the growing field of small satellites," AMSAT concluded.
"Experiments conducted by amateur satellites...continue to inform
the development of the commercial small satellite industry.
Additionally, student participation in amateur satellite projects
provides both inspiration for young men and women to pursue careers
in the commercial satellite industry and practical experience for
those careers.

"A strong and robust amateur satellite service will continue to
benefit the public interest and inspire future developments in
satellite technology," AMSAT said. "Continued progress in achieving
these goals requires adequate spectrum, especially in suitable
microwave bands."
NNNN
/EX
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SB SPACE @ ARL $ARLS005
ARLS005 First Element of ARISS Next-Generation Radio System
Installed and Operating on ISS

ZCZC AS05
QST de W1AW
Space Bulletin 005 ARLS005
From ARRL Headquarters
Newington, CT September 2, 2020
To all radio amateurs

SB SPACE ARL ARLS005
ARLS005 First Element of ARISS Next-Generation Radio System
Installed and Operating on ISS

The initial element of the Amateur Radio on the International Space
Station (ARISS) next-generation radio system has been installed
onboard the ISS, and amateur radio operations using the new gear are
now under way.

The first element, dubbed the InterOperable Radio System (IORS), was
installed in the ISS Columbus module. The IORS replaces the Ericsson
radio system and packet module that were originally certified for
spaceflight in mid-2000.

"Finally! It's been a scramble the last few days with coordination
over the weekend and yesterday with astronaut Chris Cassidy,
KF5KDR," ARISS-US Delegate for ARRL Rosalie White, K1STO, said. "But
the new ARISS radio system is now installed, set up, and
functioning. What a long road we've traveled over the past 5 years!"

Initial operation of the new radio system is in FM cross-band
repeater mode using an uplink of 145.99 MHz (CTCSS 67 Hz) and a
downlink of 437.800 MHz. System activation was first observed at
01:02 UTC on September 2. Special operations will continue to be
announced, ARISS said.

The IORS was launched from Kennedy Space Center last March onboard
the SpaceX CRS-20 resupply mission. It consists of a special,
"space-modified" JVC-Kenwood D710GA transceiver, an ARISS-developed multi-voltage power supply, and interconnecting cables. The design, development, fabrication, testing, and launch of the first IORS was
the culmination of a 5-year engineering effort by the ARISS hardware
team of volunteers.

ARISS says the system "will enable new, exciting capabilities for
ham radio operators, students, and the general public." Capabilities
include a higher-power radio, voice repeater, digital packet radio
(APRS) capabilities, and a Kenwood VC-H1 slow-scan television (SSTV)
system.

A second IORS will undergo flight certification for later launch and installation in the Russian Service Module. The second system
enables dual, simultaneous operations, such as voice repeater and
APRS packet. It also provides on-orbit redundancy to ensure
continuous operations in the event of an IORS component failure.

"Next-gen development efforts continue," ARISS said. "For the IORS,
parts are being procured and a total of 10 systems are being
fabricated to support flight, additional flight spares, ground
testing, and astronaut training." Follow-on next-generation radio
system elements include L-band repeater uplink capability -
currently in development - and a flight Raspberry-Pi, dubbed
"ARISS-Pi," that is just in the design phase. The ARISS-Pi promises
operations autonomy and enhanced SSTV operations, ARISS explained.

ARISS this year marks 20 years of continuous amateur radio
operations on the ISS.
NNNN
/EX
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SB SPACE @ ARL $ARLS006
ARLS006 Slow-Scan Television Transmissions from ISS Planned

ZCZC AS06
QST de W1AW
Space Bulletin 006 ARLS006
From ARRL Headquarters
Newington, CT September 29, 2020
To all radio amateurs

SB SPACE ARL ARLS006
ARLS006 Slow-Scan Television Transmissions from ISS Planned

A Moscow Aviation Institute MAI-75 slow-scan television (SSTV)
experiment event is planned for Wednesday, September 30, from 1305
UTC to 1845 UTC, and Thursday, October 1, from 1230 UTC to 1745 UTC.
SSTV signals will be transmitted on 145.800 MHz, plus/minus Doppler
shift.

The expected mode will be PD 120, and the call sign will be RS0ISS.
Received images of reasonable quality may be posted on the ARISS
SSTV Gallery at, https://www.spaceflightsoftware.com/ARISS_SSTV/ .
NNNN
/EX
--- SBBSecho 3.11-Win32
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SB SPACE @ ARL $ARLS007
ARLS007 Chinese Amateur Radio Satellite Launches Delayed

ZCZC AS07
QST de W1AW
Space Bulletin 007 ARLS007
From ARRL Headquarters
Newington, CT September 29, 2020
To all radio amateurs

SB SPACE ARL ARLS007
ARLS007 Chinese Amateur Radio Satellite Launches Delayed

CAMSAT says the CAS-7A launch has been postponed until next May, and
CAS-5A until next June.

"Because of COVID-19, many things have been delayed," CAMSAT's Alan
Kung, BA1DU, told ARRL. He said an announcement would be made closer
to the announced launches.

CAMSAT said last spring that CAS-7A would launch in mid-September;
the launch has been postponed multiple times since first announced.
CAS-5A was predicted to launch in October. Both satellites will
carry two transponders that include HF, in a configuration similar
to that of the Russian RS satellites decades ago.

CAS-7A will be placed into a sun-synchronous orbit with an
inclination of 98 degrees at 500 kilometers above Earth. The
transponders will have a bandwidth of 30 kHz. According to the IARU
amateur satellite frequency coordination page, the HF/HF linear
transponder will uplink on 15 meters - 21.245 to 21.275 MHz, and
downlink on 10 meters - 29.435 to 29.465 MHz. A CW beacon will
transmit on 29.425 MHz. The HF/UHF transponder will uplink at
21.3125 to 21.3275 MHz, and downlink at 435.3575 to 435.3725 MHz. A
CW beacon for that transponder will transmit on 435.430 MHz.

The CAS-5A nanosatellite, with a 6U form factor, carries two HF
transponders and two VHF/UHF transponders. While in orbit, it will
deploy the tiny CAS-5B femtosatellite, which will weigh just 0.5
kilogram.

The array of CAS-5A linear transponders will include HF/HF, HF/UHF,
and VHF/UHF with 30-kHz passbands (except 15 kHz for the HF/UHF
transponder).

CAS-5A will include CW telemetry beacons on HF and UHF. The HF CW
beacon will be at 29.465 MHz, and a UHF telemetry beacon will be at
435.57 MHz. Other beacons include the HF/HF transponder beacon at
29.490 MHz; the HF/UHF transponder beacon at 435.505 MHz, and the
VHF/UHF transponder beacon at 435.540 MHz.

Telemetry will be transmitted at 435.650 MHz. The V/U linear
transponder will uplink at 145.820 MHz; the V/U FM transponder will
uplink at 145.925 MHz. Terrestrial stations will access the
transponders at 21.385 - 21.415 MHz.
NNNN
/EX
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SB SPACE @ ARL $ARLS008
ARLS008 An ARISS Slow-Scan TV Event from the ISS is Scheduled

ZCZC AS08
QST de W1AW
Space Bulletin 008 ARLS008
From ARRL Headquarters
Newington, CT October 5, 2020
To all radio amateurs

SB SPACE ARL ARLS008

ARLS008 An ARISS Slow-Scan TV Event from the ISS is Scheduled

An Amateur Radio on the International Space Station (ARISS)
slow-scan television (SSTV) event from the ISS is set to begin on
October 4 at 1400 UTC for setup and operation, continuing until
October 8 at 1915 UTC. Dates and times are subject to change, due to
ISS operational adjustments. Images will be downlinked at 145.800
MHz +/- 3 kHz for Doppler shift. The expected SSTV mode is PD 120.

The main theme of this collection of images will be satellites.
Radio enthusiasts participating in the event can post and view
images on the ARISS SSTV Gallery at, https://www.spaceflightsoftware.com/ARISS_SSTV/ .

After your image is posted, you can acquire a special award by
visiting https://ariss.pzk.org.pl/sstv/ and following directions for
submitting a digital copy of your received image.
NNNN
/EX
--- SBBSecho 3.11-Win32
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SB SPACE @ ARL $ARLS009
ARLS009 ARRL Comments in Orbital Debris Mitigation Proceeding

ZCZC AS09
QST de W1AW
Space Bulletin 009 ARLS009
From ARRL Headquarters
Newington, CT October 14, 2020
To all radio amateurs

SB SPACE ARL ARLS009
ARLS009 ARRL Comments in Orbital Debris Mitigation Proceeding

In comments to the FCC, ARRL targeted two specific areas of concern
regarding a Further Notice of Proposed Rulemaking (FNPRM) in IB
Docket 18-313 - mitigation of orbital debris in the new space age.

In an earlier phase of the proceeding, ARRL filed comments and met
with FCC staff to discuss the proposed rules. In comments filed on
October 9, ARRL focused on the areas of indemnification and maneuverability/propulsion. Indemnification places the liability for
any possible damage from a satellite on an individual or entity.
ARRL reiterated its assertion that, as a practical matter, an
indemnification requirement "would seriously impair the ability of
amateur and university experimenters to launch and operate
satellites under US auspices" due to the potential liability and
high insurance cost.

The FNPRM can be found online in PDF format at, https://docs.fcc.gov/public/attachments/FCC-20-54A1.pdf .

ARRL's comments cited a letter from University Small Satellite
Researchers, submitted on behalf of 24 named professors last April,
contending that the requirement "would effectively preclude a large
proportion of academic SmallSat missions because public universities
typically cannot legally enter into indemnification arrangements."

ARRL argued that if the FCC does adopt an indemnification
requirement, it should allow either the owner or the licensee of an
amateur space station to provide indemnification. In the Amateur
Satellite Service a licensee can only be an individual. An
individual licensee is unlikely to accept liability for a satellite,
but a satellite owner might. In its own comments, AMSAT similarly
asked for language that would allow satellite owners as well as
licensees to indemnify the US for the operation of an amateur radio
satellite.

The FCC proposal also would require that all space stations deployed
in low-Earth orbits higher than 400 kilometers (about 250 miles) be
able to maneuver with the use of some sort of onboard propulsion
system. ARRL urged adoption of an exception for "a limited number of
amateur and similar experimental satellites" that are below a
specified size and mass and either standalone spacecraft or in a
constellation of no more than four or five individual satellites.
ARRL suggested a size limit of 36 x 24 x 12 centimeters and 12
kilograms in mass.

"This would accommodate the types of small satellites most often
used for experimental purposes by radio amateurs," ARRL told the
FCC. "Such satellites are small in number [and] have limited to no
capacity to implement maneuverability using current technology due
to their small size," yet provide valuable platforms for
experimentation and student experience.

Alternatively, ARRL asked the FCC to consider increasing the
400-kilometer low-Earth orbit limit, since satellites placed into
orbit from the ISS and from ISS service vehicles "often are in
higher orbits but share the same characteristics as those that orbit
below 400 kilometers." Doing so would help to preserve the
educational and experimental benefit of such satellites, ARRL said,
provided "such vehicles are shown to pose no risk to the
International Space Station and will return to Earth within the
specified time limit."

In concluding its remarks, ARRL asked for "reasonable
accommodation," given the public benefit of the Amateur Satellite
Service, rather than lumping small experimenters and researchers
with large corporate entities planning to launch thousands of
satellites.
NNNN
/EX
--- SBBSecho 3.11-Win32
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SB SPACE @ ARL $ARLS010
ARLS010 Neutron-1 CubeSat Scheduled for Deployment on November 5;
Other Sats Pending

ZCZC AS10
QST de W1AW
Space Bulletin 010 ARLS010
From ARRL Headquarters
Newington, CT November 4, 2020
To all radio amateurs

SB SPACE ARL ARLS010
ARLS010 Neutron-1 CubeSat Scheduled for Deployment on November 5;
Other Sats Pending

The 3-U Neutron-1 CubeSat is scheduled for deployment from the
International Space Station (ISS) on November 5 at 10:40 UTC. For
the satellite's first month and during its commissioning phase, the
Neutron-1 beacon will transmit 1,200 bps BPSK telemetry every 60
seconds on 435.300 MHz. Developed by the Hawaii Space Flight
Laboratory (HSFL) at the University of Hawaii at Manoa (UHM), the
satellite's payload includes a VU FM amateur radio repeater during
available times and according to the spacecraft's power budget. The
Neutron-1 science mission is spelled out in a formal paper,
Neutron-1 Mission: Low Earth Orbit Neutron Flux Detection and COSMOS
Mission Operations Technology Demonstration.

More information can be found online at,
https://www.hsfl.hawaii.edu/ .

HSFL operates and maintains a satellite UHF, VHF, and L/S-band
amateur radio ground station at Kauai Community College.

The primary mission of Neutron-1 is to measure low-energy neutron
flux in low-Earth orbit (LEO). The science payload, a small neutron
detector developed by Arizona State University, will focus on
measurements of low-energy secondary neutrons - a component of the
LEO neutron environment.

A number of other amateur radio satellites are expected to launch or
be deployed in the next few months. AMSAT's RadFxSat-2 (Fox-1E) is
expected to go into orbit by year's end on Virgin Orbit's
LauncherOne vehicle. RadFxSat-2 carries a 30 kHz wide VU linear
transponder.

The Tevel Mission - a series of eight Israeli 1U CubeSats, each
carrying a UV FM transponder - is expected to launch from India on a
SpaceX Falcon 9 rocket in December. Also from the Herzliya Science
Center is a 3U CubeSat called Tausat-1, which is scheduled to launch
on a Japan Aerospace Exploration Agency (JAXA) ISS resupply mission
in February for subsequent deployment. Tausat-1 carries an FM
transponder.

AMSAT-Spain (AMSAT-EA) reports that its PocketQubes, EASAT-2, and
HADES, have been integrated for launch on a SpaceX Falcon 9 in
December, while GENESIS-L and GENESIS-N have been integrated for
launch on Firefly's Alpha rocket.
NNNN
/EX
--- SBBSecho 3.11-Win32
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SB SPACE @ ARL $ARLS001
ARLS001 AMSAT/Vanderbilt RadFXSat-2/Fox 1E Set to Launch

ZCZC AS01
QST de W1AW
Space Bulletin 001 ARLS001
From ARRL Headquarters
Newington, CT January 12, 2021
To all radio amateurs

SB SPACE ARL ARLS001
ARLS001 AMSAT/Vanderbilt RadFXSat-2/Fox 1E Set to Launch

Virgin Orbit's LauncherOne is a go for launch on Wednesday, January
13, at 1500 UTC, carrying the AMSAT/Vanderbilt RadFXSat-2/Fox-1E
CubeSat into space.

The LauncherOne vehicle will carry 10 other satellites.
RadFXSat-2/Fox-1E carries an inverting linear transponder, with
uplink at 145.860 MHz - 145.890 MHz, and downlink at 435.760 MHz -
435.790 MHz.

Telemetry will downlink on 435.750 MHz. More information is on the
Space Launch Now website at, https://spacelaunchnow.me/launch/launcherone-launch-demo-2/ .
NNNN
/EX
--- SBBSecho 3.11-Win32
* Origin: The Thunderbolt BBS - tbolt.synchro.net (454:1/33)

SB SPACE @ ARL $ARLS002
ARLS002 RadFxSat-2 Satellite Signals Detected, AMSAT Engineering
Continues to Assess Status

ZCZC AS02
QST de W1AW
Space Bulletin 002 ARLS002
From ARRL Headquarters
Newington, CT January 29, 2021
To all radio amateurs

SB SPACE ARL ARLS002
ARLS002 RadFxSat-2 Satellite Signals Detected, AMSAT Engineering
Continues to Assess Status

AMSAT reports that it's continuing to assess the status of the
RadFxSat-2 / Fox-1E amateur radio CubeSat after a ham in Nevada
reported hearing his CW signal weakly via the spacecraft's
transponder on January 27. AMSAT Engineering and Operations was able
to confirm the reports from Brad Schumacher, W5SAT, and determined
that RadFxSat-2 is partially functioning, although signals are
extremely weak.

"We also appreciate those who joined in determining whether they
could detect their own or other signals in recent passes today,"
AMSAT said in a January 28 bulletin. "Please do not attempt to
transmit through the transponder until further notice. This is very
important to the next steps we are taking now."

The next crucial step in evaluating the condition of RadFxSat-2 is
to determine whether or not the 1200 bps BPSK telemetry beacon is
operating and, if possible, to copy telemetry from the beacon. AMSAT
continues to ask that those with 70-centimeter receive capability
listen on the beacon frequency of 435.750 MHz, +/- Doppler, upper
sideband (USB). Use FoxTelem to capture any telemetry, and set
FoxTelem to "Upload to Server" so that AMSAT will receive the
telemetry data.

Recordings are welcome, with a detailed description, at,
foxtelem@amsat.us .

FoxTelem can be found at, https://www.amsat.org/foxtelem-software-for-windows-mac-linux/ .

AMSAT stressed that keeping the RadFxSat-2 / Fox-1E transponder
clear "is essential to putting all power and attention to the beacon telemetry." Available data suggest that RadFxSat-2 is OBJECT M from
the Virgin Orbit LauncherOne launch, NORAD ID 47320, international
designation 21-002M.

"We thank the amateur satellite community for their perseverance and
assistance while the AMSAT Engineering and Operations teams work to
understand and resolve the situation with RadFxSat-2," AMSAT said.
NNNN
/EX
--- SBBSecho 3.11-Win32
* Origin: The Thunderbolt BBS - tbolt.synchro.net (454:1/33)

SB SPACE @ ARL $ARLS003
ARLS003 CAPE-3 CubeSat Launched

ZCZC AS03
QST de W1AW
Space Bulletin 003 ARLS003
From ARRL Headquarters
Newington, CT February 16, 2021
To all radio amateurs

SB SPACE ARL ARLS003
ARLS003 CAPE-3 CubeSat Launched

The University of Louisiana (UL) at Lafayette student-built CAPE-3
satellite was launched on January 17. A 1-U CubeSat, CAPE-3 includes
a "digipeater and experimental UHF adaptive radio." An AX-25
telemetry downlink has been coordinated on 145.825 MHz and a 1k2 frequency-shift keying (FSK) downlink has been coordinated on
435.325 MHz, "which may burst to 100 kHz bandwidth," according to
the IARU Amateur Satellite Coordination page.

CAPE-3 is the third cube satellite in the CAPE series. The primary
educational mission is to allow grade-school classrooms to access
the Smartphone CubeSat Classroom, and run interactive experiments
through an experimental smartphone ground-station grid.

The secondary mission is to perform scientific experiments involving
radiation detection and take pictures of Earth.

The solar-powered spacecraft, created by UL Lafayette's CAPE
Satellite Team, was launched with nine other CubeSats as part of
NASA's Educational Launch of Nanosatellites (ELaNa) program. A
Virgin Orbit LauncherOne rocket attached beneath a wing of a
customized Boeing 747 was dropped high above the Pacific Ocean. It
climbed about 225 miles above Earth and then ejected the satellite.

Information on the ElaNa program can be found in PDF format at, https://www.nasa.gov/sites/default/files/atoms/files/ lsp_elana_20_fact_sheet.pdf
.

(above URL all on one line)

The CAPE satellites are named for the university's Cajun Advanced
Picosatellite Experiment program, designed to prepare students for
careers in science, technology, engineering, and mathematics (STEM)
fields.
NNNN
/EX
--- SBBSecho 3.11-Win32
* Origin: The Thunderbolt BBS - tbolt.synchro.net (454:1/33)

SB SPACE @ ARL $ARLS007
ARLS007 Slow-Scan TV Event from International Space Station Set

ZCZC AS07
QST de W1AW
Space Bulletin 007 ARLS007
From ARRL Headquarters
Newington, CT June 17, 2021
To all radio amateurs

SB SPACE ARL ARLS007
ARLS007 Slow-Scan TV Event from International Space Station Set

A slow-scan television (SSTV) event from June 21 - 26 will focus on
amateur radio on the Space Shuttle, the Mir space station, and the International Space Station, Amateur Radio on the International
Space Station (ARISS) has announced. Transmissions will be on
145.800 MHz FM using PD120 SSTV mode.

"The ARISS team will be transmitting SSTV images continuously from
June 21 until June 26," ARISS said in announcing the upcoming event.
"The images will be related to some of the amateur radio activities
that have occurred on the space shuttle, the Mir space station, and
the International Space Station."

Transmissions will start at or about 0940 UTC on Monday, June 21 and
will end by 1830 UTC on Saturday, June 26. "Those that recently
missed the opportunity during the limited period of MAI
transmissions should have numerous chances over the 6-day period to
capture many - if not all 12 - of the images."

The ARISS SSTV blog - located at http://ariss-sstv.blogspot.com/ -
will post the latest information. Signals should be receivable on a
handheld with a quarter-wave whip antenna. Use 25 kHz channel
spacing if available.

Pass time predictions are available on the AMSAT website at, https://www.amsat.org/track/ .
NNNN
/EX
--- SBBSecho 3.14-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)

SB SPACE @ ARL $ARLS008
ARLS008 MIR-SAT1 CubeSat Expected to Deploy from the ISS on June 22

ZCZC AS08
QST de W1AW
Space Bulletin 008 ARLS008
From ARRL Headquarters
Newington, CT June 21, 2021
To all radio amateurs

SB SPACE ARL ARLS008
ARLS008 MIR-SAT1 CubeSat Expected to Deploy from the ISS on June 22

MIR-SAT1 (Mauritius Imagery and Radiotelecommunication Satellite 1),
the first amateur radio CubeSat from the Indian Ocean island nation
of Mauritius, is expected to be deployed from the International
Space Station (ISS) on June 22.

MIR-SAT1 will carry an amateur radio V/U digipeater (a downlink of
436.925 MHz has been coordinated). MIR-SAT1 will collect images of
the Republic of Mauritius and its Exclusive Economic Zone (EEZ)
using an onboard camera.

The 1U nanosatellite was designed by a team of Mauritian engineers
and radio amateurs and built by the Mauritius Research and
Innovation Council (MRIC). MIR-SAT1 will be available to the amateur
community when the satellite is not in use for other purposes.
NNNN
/EX
--- SBBSecho 3.14-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)

SB SPACE @ ARL $ARLS011
ARLS011 ISS SSTV Transmission Set for Late December

ZCZC AS11
QST de W1AW
Space Bulletin 011 ARLS011
From ARRL Headquarters
Newington, CT December 21, 2021
To all radio amateurs

SB SPACE ARL ARLS011
ARLS011 ISS SSTV Transmission Set for Late December

The Amateur Radio on the International Space Station (ARISS) team
will support Slow Scan TV (SSTV) transmissions from the
International Space Station (ISS), December 26 - 31. The images will
be related to lunar exploration.

Transmissions should be available worldwide on 145.800 MHz FM, using
SSTV mode PD120.

Transmissions are set to start on December 26 at about 1825 UTC and
end December 31 at about 1705 UTC. The signal should be receivable
on a handheld transceiver with a quarter-wave whip antenna. Use the
widest filter for 25 kHz channel spacing.

The ARISS-SSTV blog has more information,
http://ariss-sstv.blogspot.com/ . Visit the AMSAT Online Satellite
Pass Predictions page for ISS pass times at,
https://www.amsat.org/track/ .
NNNN
/EX
--- SBBSecho 3.14-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)

SB SPACE @ ARL $ARLS012
ARLS012 New Chinese Amateur Radio Satellite Could Launch on December
25

ZCZC AS12
QST de W1AW
Space Bulletin 012 ARLS012
From ARRL Headquarters
Newington, CT December 21, 2021
To all radio amateurs

SB SPACE ARL ARLS012
ARLS012 New Chinese Amateur Radio Satellite Could Launch on December
25

The CAMSAT XW-3 (CAS-9) amateur radio satellite has been installed
on the CZ-4C Y39 launch vehicle at the Taiyuan Satellite Launch
Center in China, and related work is in progress as planned,
CAMSAT's Alan Kung, BA1DU, reports.

"If all goes well, the satellite will be launched on December 25,
2021." The orbit will be a circular Sun-synchronous orbit with an
altitude of 770.1 kilometers. The XW-3 (CAS-9) user manual has more
details.

The 100 mW linear transponder will have an uplink frequency of
145.870 MHz and a downlink frequency of 435.18 MHz (transponder
passband is 30 kHz, inverted). The satellite will have a CW beacon
on 435.575 MHz.
NNNN
/EX
--- SBBSecho 3.14-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)

SB SPACE @ ARL $ARLS002
ARLS002 Eight-Satellite TEVEL Mission to Launch on January 13

ZCZC AS02
QST de W1AW
Space Bulletin 002 ARLS002
From ARRL Headquarters
Newington, CT January 12, 2022
To all radio amateurs

SB SPACE ARL ARLS002
ARLS002 Eight-Satellite TEVEL Mission to Launch on January 13

The TEVEL mission, which consists of eight satellites carrying
amateur radio FM transponders, is set to launch on January 13 at
1525 UTC on the SpaceX Falcon 9 Transporter-3 mission, which also
carries AMSAT-Spain's (AMSAT-EA) EASAT-2 and HADES satellites.
(Please see 2022 Space Bulletin ARLS001 for more information about
the AMSAT-EA satellites.)

The TEVEL satellites were developed by the Herzliya Science Center
in Israel.

All eight satellites will use the same frequencies, as long as their
footprints overlap, and only one FM transponder will be activated at
a time. Beacon transmissions will be on 436.400 MHz (9,600 bps
BPSK). The uplink frequency of the FM transponders is 145.970 MHz,
and the downlink frequency is 436.400 MHz. The satellites were built
by eight schools in different parts of Israel.
NNNN
/EX
--- SBBSecho 3.14-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)

SB SPACE @ ARL $ARLS001
ARLS001 More Amateur Radio Astronauts Head for the International
Space Station

ZCZC AS01 
QST de W1AW 
Space Bulletin 001 ARLS001
From ARRL Headquarters 
Newington, CT January 9, 2023
To all radio amateurs

SB SPACE ARL ARLS001
ARLS001 More Amateur Radio Astronauts Head for the International
Space Station

Three of the four new astronauts on February's planned launch of the
SpaceX Crew-6 mission to the International Space Station (ISS) are
amateur radio operators.

The four crew members that comprise the SpaceX Crew-6 mission are,
Mission Specialist Andrey Fedyaev, Pilot Warren "Woody" Hoburg,
Mission Specialist Sultan Al Nedayi, and Commander Stephen Bowen.
Photo Courtesy of SpaceX.

Pilot Warren "Woody" Hoburg, KB3HTZ; Commander Stephen Bowen,
KI5BKB, and Mission Specialist Sultan Al Neyadi, KI5VTV, will join
Mission Specialist Andrey Fedyaev on board the SpaceX Dragon
spacecraft, Endeavour.

The spacecraft will be atop a Falcon 9 rocket and, while a launch
date has not been selected, the earliest date would be mid-February
2023.

All crew members have learned about Amateur Radio on the
International Space Station (ARISS), received guidance on studying
and testing, and learned how to operate the ARISS radios and the
basics of on-the-air protocol from ARISS team members at NASA's
Johnson Space Center.

The crew will be able to participate in ARISS, using the ham radio
station on the ISS to contact schools and other educational
institutions.

ARISS is a cooperative venture of international amateur radio
societies and the space agencies that support the ISS. In the US,
participating organizations include NASA, the ISS National Lab, ARRL
The National Association for Amateur Radio, and AMSAT.
NNNN
/EX
--- SBBSecho 3.15-Win32
* Origin: The Thunderbolt BBS - Little Rock, Arkansas (454:1/33)