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High-altitude balloon

May 02, 2024

"Space balloon" redirects here. For balloon space probes, see List of Solar System probes. For balloon-based in-space satellites, see balloon satellite. For balloon spacecraft, see inflatable decelerator.

High-altitude balloons or stratostats are usually uncrewed balloons typically filled with helium or hydrogen and released into the stratosphere, generally attaining between 18 and 37 km (11 and 23 mi; 59,000 and 121,000 ft) above sea level. In 2013, a balloon named BS 13-08 reached a record altitude of 53.7 km (33.4 mi; 176,000 ft).[1]

The BLAST high-altitude balloon just before launch on June 12, 2005

The most common type of high-altitude balloons are weather balloons. Other purposes include use as a platform for experiments in the upper atmosphere. Modern balloons generally contain electronic equipment such as radio transmitters, cameras, or satellite navigation systems, such as GPS receivers. Hobbyists frequently purchase weather balloons because of its ease of use, low price point, and its widespread commoditisation.

These balloons are launched into what is defined as "near space", defined as the area of Earth's atmosphere between the Armstrong limit (18–19 km (11–12 mi) above sea level), where pressure falls to the point that a human being cannot survive without a pressurised suit, and the Kármán line (100 km (62 mi) above sea level[2]), where astrodynamics must take over from aerodynamics in order to maintain flight.

Due to the low cost of GPS and communications equipment, high-altitude ballooning is a popular hobby, with organizations such as UKHAS assisting the development of payloads.[3][4]

An example image from a hobby high-altitude balloon launched by the Make Stuff Club from Kalamazoo College
A photo taken from a 1,500 g (3.3 lb) weather balloon at approximately 100,000 ft (19 mi; 30 km) above Oregon
A latex weather balloon bursting at about 29.5 km (18.3 mi; 97,000 ft)

History edit

The first hydrogen balloon edit

In France during 1783, the first public experiment with hydrogen-filled balloons involved Jacques Charles, a French professor of physics, and the Robert brothers, renowned constructors of physics instruments.

Charles provided large quantities of hydrogen, which had only been produced in small quantities previously, by mixing 540 kg (1,190 lb) of iron and 270 kg (600 lb) of sulfuric acid. The balloon took 5 days to fill and was launched from Champ de Mars in Paris where 300,000 people gathered to watch the spectacle. The balloon was launched and rose through the clouds. The expansion of the gas caused the balloon to tear and it descended 45 minutes later 20 km (12 mi) away from Paris.[5]

Crewed high-altitude balloons edit

Crewed high-altitude balloons have been used since the 1930s for research and in seeking flight altitude records, including Auguste Piccard's flights up to 16,201m, the Soviet Osoaviakhim-1 at 22,000m, and the American Explorer II at 22,066m.[6] Notable crewed high altitude balloon flights include three records set for highest skydive, the first set by Joseph Kittinger in 1960 at 31,300m for Project Excelsior, followed by Felix Baumgartner in 2012 at 38,969m for Red Bull Stratos and most recently Alan Eustace in 2014 at 41,419m.

Uses edit

Uncrewed high-altitude balloons are used as research balloons, for educational purposes, and by hobbyists. Common uses include meteorology, atmospheric and climate research, collection of imagery from near space, amateur radio applications, and submillimetre astronomy.

High-altitude balloons have been considered for use in telecommunications[7] and space tourism.[6] Private companies such as Zero 2 Infinity, Space Perspective, Zephalto, and World View Enterprises are developing both crewed and uncrewed high-altitude balloons for scientific research, commercial purposes, and space tourism.[8][9] High-altitude platform stations have been proposed for applications such as communications relays.

Amateur high-altitude ballooning edit

 
Payload of an amateur high-altitude balloon for scientific purposes. Embedded computer Arietta G25, custom pcb and different sensors (temperature, pressure, passive radiation detector). Photo taken after the flight.

In many countries, the bureaucratic overhead required for high altitude balloon launches is minimal when the payload is below a certain weight threshold, typically on the order of a few kilograms.[10][11] This makes the process of launching these small HABs accessible to many students and amateur groups. Despite their smaller size, these HABs still often ascend to (and past) altitudes on the order of 30,000 m (98,000 ft), providing easy stratospheric access for scientific and educational purposes.[12][3][4][13][14][15] These amateur balloon flights are often informed in their operations by the use of a path predictor. Before launch, weather forecasts containing predicted wind vectors are used to numerically propagate a simulated HAB along a trajectory, predicting where the actual balloon will travel.[16]

Amateur radio high-altitude ballooning edit

Testing radio range is often a large component of these hobbies. Amateur radio is often used with packet radio to communicate with 1200 baud, using a system called Automatic Packet Reporting System back to the ground station. Smaller packages called micro or pico trackers are also built and run under smaller balloons. These smaller trackers have used Morse code, Field Hell, and RTTY to transmit their locations and other data.[17]

The first recorded amateur radio high-altitude balloon launches took place in Finland by the Ilmari program on May 28, 1967, and in Germany in 1964.[18]

ARHAB program edit

 
Image of the Earth's horizon taken from 26 km (16 mi) on an ARHAB flight.

Amateur radio high-altitude ballooning (ARHAB) is the application of analog and digital amateur radio to weather balloons and was the name suggested by Ralph Wallio (amateur radio callsign W0RPK) for this hobby. Often referred to as "The Poorman's Space Program", ARHAB allows amateurs to design functioning models of spacecraft and launch them into a space-like environment. Bill Brown (amateur radio callsign WB8ELK) is considered to have begun the modern ARHAB movement with his first launch of a balloon carrying an amateur radio transmitter on 15 August 1987.

An ARHAB flight consists of a balloon, a recovery parachute, and a payload of one or more packages. The payload normally contains an amateur radio transmitter that permits tracking of the flight to its landing for recovery. Most flights use an Automatic Packet Reporting System (APRS) tracker which gets its position from a Global Positioning System (GPS) receiver and converts it to a digital radio transmission. Other flights may use an analog beacon and are tracked using radio direction finding techniques. Long duration flights frequently must use high frequency custom-built transmitters and slow data protocols such as radioteletype (RTTY), Hellschreiber, Morse code and PSK31, to transmit data over great distances using little battery power. The use of amateur radio transmitters on an ARHAB flight requires an amateur radio license, but non-amateur radio transmitters are possible to use without a license.

In addition to the tracking equipment, other payload components may include sensors, data loggers, cameras, amateur television (ATV) transmitters or other scientific instruments. Some ARHAB flights carry a simplified payload package called BalloonSat.

A typical ARHAB flight uses a standard latex weather balloon, lasts around 2–3 hours, and reaches 25–35 km (16–22 mi) in altitude. Experiments with zero-pressure balloons, superpressure balloons, and valved latex balloons have extended flight times to more than 24 hours. A zero-pressure flight by the Spirit of Knoxville Balloon Program in March 2008 lasted over 40 hours and landed off the coast of Ireland, over 5,400 km (3,400 mi) from its launch point. On December 11, 2011, the California Near Space Project flight number CNSP-11 with the call sign K6RPT-11 launched a record-breaking flight traveling 6,236 mi (10,036 km) from San Jose, California, to a splashdown in the Mediterranean Sea. The flight lasted 57 hours and 2 minutes. It became the first successful U.S. transcontinental and the first successful transatlantic amateur radio high-altitude balloon.[19][20][21][22] Since that time, a number of flights have circumnavigated the Earth using superpressure plastic film balloons.[23][24]

Each year in the United States, the Great Plains Super Launch (GPSL) hosts a large gathering of ARHAB groups.

BEAR program edit

Balloon Experiments with Amateur Radio (BEAR) is a series of Canadian-based high-altitude balloon experiments by a group of Amateur Radio operators and experimenters from Sherwood Park and Edmonton, Alberta. The experiments started in the year 2000 and continued with BEAR-9 in 2012, reaching 36.010 km (22.376 mi).[25][26] The balloons are made of latex filled with either helium or hydrogen. All of the BEAR payloads carry a tracking system comprising a GPS receiver, an APRS encoder, and a radio transmitter module. Other experimental payload modules include an Amateur Radio crossband repeater, and a digital camera, all of which is contained within an insulated foam box suspended below the balloon.

BalloonSat edit

 
Image of five BalloonSats shortly after launch on an ARHAB flight.

A BalloonSat is a simple package designed to carry lightweight experiments into near space.[27] They are a popular introduction to engineering principles in some high school and college courses. BalloonSats are carried as secondary payloads on ARHAB flights. One reason BalloonSats are simple is that they do not require the inclusion of tracking equipment; as secondary payloads, they already are being carried by tracking capsules.

Space Grant started the BalloonSat program in August 2000. It was created as a hands-on way to introduce new science and engineering students interested in space studies to some fundamental engineering techniques, team working skills and the basics of space and Earth science. The BalloonSat program is part of a course taught by Space Grant at the University of Colorado at Boulder.[28]

Often the design of a BalloonSat is under weight and volume constraints. This encourages good engineering practices, introduces a challenge, and allows for the inclusion of many BalloonSats on an ARHAB flight. The airframe material is usually Styrofoam or Foamcore, as they are lightweight, easy to machine, and provide reasonably good insulation.

Most carry sensors, data loggers and small cameras operated by timer circuits. Popular sensors include air temperature, relative humidity, tilt, and acceleration. Experiments carried inside BalloonSats have included such things as captive insects and food items.

Before launch, most BalloonSats are required to undergo testing. These tests are designed to ensure the BalloonSat will function properly and return science results. The tests include a cold soak, drop test, function test, and weighing. The cold soak test simulates the intense cold temperatures the BalloonSat will experience during its mission. A launch and landing can be traumatic, therefore the drop test requires the BalloonSat to hold together and still function after an abrupt drop. The function test verifies the BalloonSat crew can prepare the BalloonSat at the launch site.

Variety payloads edit

Besides conducting scientific activities, schools, influencers and other individuals have launched a wide variety of novelty payloads to the stratosphere with high-altitude balloons. These have included teddy bears,[29] LEGO figurines,[30][31] hamburgers,[31] pizza,[32][33][34] Cornish pasties,[35] garlic bread,[36] bacon and cans of beer.[31] Japanese electronics manufacturer Toshiba attempted to record an advertisement in near space with an armchair and cameras tethered to a high-altitude balloon.[31]

Geostationary balloon satellite edit

See also: Geostationary satellite, Atmospheric satellite, and Solar-powered aircraft
 
Stratobus airship
 
Geostationary balloon satellite
 
Geostationary airship satellite
 
High-altitude airship satellite

Geostationary balloon satellites (GBS) are proposed high-altitude balloons that would float in the mid-stratosphere (60,000 to 70,000 feet (18 to 21 km) above sea level) at a fixed point over the Earth's surface and thereby act as an atmospheric satellite. At those altitudes, air density is around 1/15 to 1/20[37] of what it is at sea level. The average wind speed at these levels is less than that at the surface.[37][38] A propulsion system would allow the balloon to move into and maintain its position. The GBS would be powered with solar panels.

A GBS could be used to provide broadband Internet access over a large area. Laser broadband would connect the GBS to the network, which could then provide a large area of coverage because of its wider line of sight over the curvature of the Earth and unimpeded Fresnel zone.[39][40][41]

Arizona space balloon port edit

World View Enterprises built and operates a balloon spaceport (high-altitude balloon port) in Pima County, Arizona.[42]

See also edit

References edit

  1. ^ "ISAS | 超薄膜高高度気球(BS13-08)が無人気球到達高度の世界記録を更新 / トピックス" [Ultra-thin film high-altitude balloon (BS13-08) breaks the world record for altitude reached by an unmanned balloon]. Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency (in Japanese). 2013-09-20. from the original on 2023-03-06. Retrieved 2023-12-03.
  2. ^ Sanz Fernández de Córdoba, Dr. S. (2004-06-24). "The 100 km Boundary for Astronautics". Fédération aéronautique internationale. Retrieved 28 December 2020.
  3. ^ a b "DIY balloon sent up 30km". Boing Boing. 26 October 2007. Retrieved 2008-06-08.
  4. ^ a b McDermott, Vincent (8 August 2011). . National Post. Archived from the original on 2013-02-28. Retrieved 2011-12-28.
  5. ^ G. Pfotzer, "History of the use of Balloons in Scientific Experiments", Space Science Reviews 13:2 pp.200 (1972). Recovered on 11 February 2009
  6. ^ a b López-Urdiales, José Mariano (October 19, 2002). (PDF). Houston, Texas. Archived from the original (PDF) on 13 July 2015. Retrieved 13 July 2015.
  7. ^ Levy, Steven (June 14, 2013). "How Google Will Use High-Flying Balloons to Deliver Internet to the Hinterlands". Wired.
  8. ^ Betancourt, Mark (July 2015). "See The World From 100,000 Feet". Air & Space. Retrieved 9 July 2015.
  9. ^ Wall, M. (2014). World View to Loft Experiments on Balloon Test Flights This Year. "Space.com." Retrieved from http://www.space.com/26658-world-view-balloon-research-flights.html
  10. ^ Civil Aviation Safety Regulations, Subpart 101.E—Unmanned free balloons. Australian Government Civil Aviation Safety Authority. 1998.
  11. ^ Code of Federal Regulations, Title 14, Chap. I, SubChap. F, Part 101. U.S. Government Publishing Office. 2020.
  12. ^ We Sent Garlic Bread to the Edge of Space, Then Ate It. Retrieved 2022-11-20 – via YouTube.
  13. ^ GSBC, What is a High Altitude Balloon 2017-07-22 at the Wayback Machine. Retrieved August 8, 2016.
  14. ^ MoCRiS, Moon Imaged from the MoCRiS Payload. Earth Science Picture of the Day (EPOD) June 25, 2019.
  15. ^ UKHAS, A Beginners Guide to High Altitude Ballooning 2016-07-29 at the Wayback Machine. Retrieved August 8, 2016.
  16. ^ Sóbester, András; Czerski, Helen; Zapponi, Niccolò; Castro, Ian (2014-04-01). "High-Altitude Gas Balloon Trajectory Prediction: A Monte Carlo Model". AIAA Journal. 52 (4): 832–842. Bibcode:2014AIAAJ..52..832S. doi:10.2514/1.J052900. ISSN 0001-1452.
  17. ^ "Amateur Radio Astronomy and weather reporting".
  18. ^ 06. Dezember 1964 - Erster Ballonstart mit Amateurfunk-Last in der DDR 2016-08-12 at the Wayback Machine (in German), accessed August 8, 2016.
  19. ^ "Amateur Radio Balloon Flight Crosses Atlantic, Sets Records". American Radio Relay League. 2011-12-15. Retrieved 2011-12-15.
  20. ^ Fernandez, Lisa (2011-12-15). "Two Silicon Valley high-altitude ballooning groups vie for record". San Jose Mercury News. Retrieved 2011-12-15.
  21. ^ Boyle, Rebecca (2011-12-15). "Amateur Radio Balloon Flies From California to Algeria". Popular Science. Retrieved 2011-12-15.
  22. ^ Meadows, Ron (2011-12-12). "CNSP-11, K6RPT-11 Flight information". California Near Space Project. Retrieved 2011-12-15.
  23. ^ "Balloons Carrying Amateur Radio Payloads Still Circling the Earth". www.arrl.org.
  24. ^ "Party Balloon Carrying Ham Radio Payload Circles Southern Hemisphere a Second Time". arrl.org.
  25. ^ Tousley, Nancy (1 March 2012). . Canadian Art. Archived from the original on 1 May 2015. Retrieved 8 August 2016.
  26. ^ Sloan, Barry. "BEAR Home Page". Retrieved 19 May 2013.
  27. ^ (PDF). Archived from the original (PDF) on 2008-05-17.
  28. ^ Koehler, Chris. "BalloonSat: Missions to the Edge of Space". Utah State University. 16th Annual/USU Conference on Small Satellites. Retrieved 18 November 2015.
  29. ^ "Teddy bear jets into outer space". www.stuff.co.nz. Retrieved 2024-03-07.
  30. ^ Pultarova, Tereza (2023-05-26). "Watch 1,000 Lego astronauts fly near the edge of space (video)". Space.com. Retrieved 2024-03-07.
  31. ^ a b c d Smithsonian Magazine. "10 Weird Things Humans Have Sent Into the Stratosphere". Smithsonian Magazine. Retrieved 2024-03-07.
  32. ^ Forbes, Paula (2012-09-17). "Watch an Entire Pizza Survive a Trip Into Space". Eater. Retrieved 2024-03-07.
  33. ^ I Sent A Slice Of Pizza To Space, Then Ate It, retrieved 2024-03-07
  34. ^ "Chef Erik stuurt pizza de ruimte in (en eet 'm daarna op)". jeugdjournaal.nl (in Dutch). 2023-05-06. Retrieved 2024-03-07.
  35. ^ "Pasty sent up by schoolchildren is Cornwall's only successful space launch to date". The Cornish Times. 2023-01-11. Retrieved 2024-03-07.
  36. ^ 2½ Hours of Unedited Garlic Bread Flight Footage, retrieved 2024-03-07
  37. ^ a b Limpinsel, Moritz; Kuo, Dawei; Vijh, Aarohi (June 2018). "SMARTS Modeling of Solar Spectra at Stratospheric Altitude and Influence on Performance of Selected III-V Solar Cells". 2018 IEEE 7th World Conference on Photovoltaic Energy Conversion (WCPEC) (A Joint Conference of 45th IEEE PVSC, 28th PVSEC & 34th EU PVSEC). IEEE. pp. 3367–3373. doi:10.1109/PVSC.2018.8547665. ISBN 978-1-5386-8529-7. On an average, wind speeds are minimum in the lower stratosphere, around 20 km altitude. Air density at 20 km is roughly 1/20 that at sea level.
  38. ^ Boccia, Luigi; Pace, Pasquale; Amendola, Giandomenico; Di Massa, Giuseppe (July 2008). "Low multipath antennas for GNSS-based attitude determination systems applied to high-altitude platforms". GPS Solutions. 12 (3): 163–171. Bibcode:2008GPSS...12..163B. doi:10.1007/s10291-007-0075-7. ISSN 1080-5370. Average wind speed in the stratosphere is minimal at altitudes of about 20 km. Values vary with season and location. Source: National Weather Service (NWS)
  39. ^ Izet-Unsalan, Kunsel; Unsalan, Deniz (2011). "A low cost alternative for satellites- tethered ultra-high altitude balloons". Proceedings of 5th International Conference on Recent Advances in Space Technologies - RAST2011. ieeexplore.ieee.org. pp. 13–16. doi:10.1109/RAST.2011.5966806. ISBN 978-1-4244-9617-4. S2CID 26712889.
  40. ^ Zee, Chong-Hung (1989-04-30). The Use of Balloons for Physics and Astronomy. Springer. ISBN 9789027726360. Retrieved 24 March 2014.
  41. ^ . noaasis.noaa.gov. Archived from the original on 25 August 2018. Retrieved 24 March 2014.
  42. ^ Emily Calandrelli (January 19, 2016). "Arizona Votes To Build Spaceport For Space Ballooning".
 
Wikimedia Commons has media related to Research balloons.

External links edit

  • (archived 26 December 2008)
  • (archived 13 February 2013)
  • StratoCat – Stratospheric balloons. History and present of their use in the fields of science, military and aerospace
  • at Parallax.com (archived 12 October 2008)
  • California Near Space Project – Silicon Valley based ARHAB group with first successful transatlantic balloon
  • – tracking team for CNSP and other balloons and rockets (archived 12 February 2003)

May 02, 2024
high, altitude, balloon, space, balloon, redirects, here, balloon, space, probes, list, solar, system, probes, balloon, based, space, satellites, balloon, satellite, balloon, spacecraft, inflatable, decelerator, stratostats, usually, uncrewed, balloons, typica. Space balloon redirects here For balloon space probes see List of Solar System probes For balloon based in space satellites see balloon satellite For balloon spacecraft see inflatable decelerator High altitude balloons or stratostats are usually uncrewed balloons typically filled with helium or hydrogen and released into the stratosphere generally attaining between 18 and 37 km 11 and 23 mi 59 000 and 121 000 ft above sea level In 2013 a balloon named BS 13 08 reached a record altitude of 53 7 km 33 4 mi 176 000 ft 1 The BLAST high altitude balloon just before launch on June 12 2005 The most common type of high altitude balloons are weather balloons Other purposes include use as a platform for experiments in the upper atmosphere Modern balloons generally contain electronic equipment such as radio transmitters cameras or satellite navigation systems such as GPS receivers Hobbyists frequently purchase weather balloons because of its ease of use low price point and its widespread commoditisation These balloons are launched into what is defined as near space defined as the area of Earth s atmosphere between the Armstrong limit 18 19 km 11 12 mi above sea level where pressure falls to the point that a human being cannot survive without a pressurised suit and the Karman line 100 km 62 mi above sea level 2 where astrodynamics must take over from aerodynamics in order to maintain flight Due to the low cost of GPS and communications equipment high altitude ballooning is a popular hobby with organizations such as UKHAS assisting the development of payloads 3 4 An example image from a hobby high altitude balloon launched by the Make Stuff Club from Kalamazoo College A photo taken from a 1 500 g 3 3 lb weather balloon at approximately 100 000 ft 19 mi 30 km above Oregon A latex weather balloon bursting at about 29 5 km 18 3 mi 97 000 ft Contents 1 History 1 1 The first hydrogen balloon 1 2 Crewed high altitude balloons 2 Uses 3 Amateur high altitude ballooning 3 1 Amateur radio high altitude ballooning 3 1 1 ARHAB program 3 1 2 BEAR program 3 2 BalloonSat 3 3 Variety payloads 4 Geostationary balloon satellite 4 1 Arizona space balloon port 5 See also 6 References 7 External linksHistory editThe first hydrogen balloon edit In France during 1783 the first public experiment with hydrogen filled balloons involved Jacques Charles a French professor of physics and the Robert brothers renowned constructors of physics instruments Charles provided large quantities of hydrogen which had only been produced in small quantities previously by mixing 540 kg 1 190 lb of iron and 270 kg 600 lb of sulfuric acid The balloon took 5 days to fill and was launched from Champ de Mars in Paris where 300 000 people gathered to watch the spectacle The balloon was launched and rose through the clouds The expansion of the gas caused the balloon to tear and it descended 45 minutes later 20 km 12 mi away from Paris 5 Crewed high altitude balloons edit Crewed high altitude balloons have been used since the 1930s for research and in seeking flight altitude records including Auguste Piccard s flights up to 16 201m the Soviet Osoaviakhim 1 at 22 000m and the American Explorer II at 22 066m 6 Notable crewed high altitude balloon flights include three records set for highest skydive the first set by Joseph Kittinger in 1960 at 31 300m for Project Excelsior followed by Felix Baumgartner in 2012 at 38 969m for Red Bull Stratos and most recently Alan Eustace in 2014 at 41 419m Uses editUncrewed high altitude balloons are used as research balloons for educational purposes and by hobbyists Common uses include meteorology atmospheric and climate research collection of imagery from near space amateur radio applications and submillimetre astronomy High altitude balloons have been considered for use in telecommunications 7 and space tourism 6 Private companies such as Zero 2 Infinity Space Perspective Zephalto and World View Enterprises are developing both crewed and uncrewed high altitude balloons for scientific research commercial purposes and space tourism 8 9 High altitude platform stations have been proposed for applications such as communications relays Amateur high altitude ballooning edit nbsp Payload of an amateur high altitude balloon for scientific purposes Embedded computer Arietta G25 custom pcb and different sensors temperature pressure passive radiation detector Photo taken after the flight In many countries the bureaucratic overhead required for high altitude balloon launches is minimal when the payload is below a certain weight threshold typically on the order of a few kilograms 10 11 This makes the process of launching these small HABs accessible to many students and amateur groups Despite their smaller size these HABs still often ascend to and past altitudes on the order of 30 000 m 98 000 ft providing easy stratospheric access for scientific and educational purposes 12 3 4 13 14 15 These amateur balloon flights are often informed in their operations by the use of a path predictor Before launch weather forecasts containing predicted wind vectors are used to numerically propagate a simulated HAB along a trajectory predicting where the actual balloon will travel 16 Amateur radio high altitude ballooning edit Testing radio range is often a large component of these hobbies Amateur radio is often used with packet radio to communicate with 1200 baud using a system called Automatic Packet Reporting System back to the ground station Smaller packages called micro or pico trackers are also built and run under smaller balloons These smaller trackers have used Morse code Field Hell and RTTY to transmit their locations and other data 17 The first recorded amateur radio high altitude balloon launches took place in Finland by the Ilmari program on May 28 1967 and in Germany in 1964 18 ARHAB program edit nbsp Image of the Earth s horizon taken from 26 km 16 mi on an ARHAB flight Amateur radio high altitude ballooning ARHAB is the application of analog and digital amateur radio to weather balloons and was the name suggested by Ralph Wallio amateur radio callsign W0RPK for this hobby Often referred to as The Poorman s Space Program ARHAB allows amateurs to design functioning models of spacecraft and launch them into a space like environment Bill Brown amateur radio callsign WB8ELK is considered to have begun the modern ARHAB movement with his first launch of a balloon carrying an amateur radio transmitter on 15 August 1987 An ARHAB flight consists of a balloon a recovery parachute and a payload of one or more packages The payload normally contains an amateur radio transmitter that permits tracking of the flight to its landing for recovery Most flights use an Automatic Packet Reporting System APRS tracker which gets its position from a Global Positioning System GPS receiver and converts it to a digital radio transmission Other flights may use an analog beacon and are tracked using radio direction finding techniques Long duration flights frequently must use high frequency custom built transmitters and slow data protocols such as radioteletype RTTY Hellschreiber Morse code and PSK31 to transmit data over great distances using little battery power The use of amateur radio transmitters on an ARHAB flight requires an amateur radio license but non amateur radio transmitters are possible to use without a license In addition to the tracking equipment other payload components may include sensors data loggers cameras amateur television ATV transmitters or other scientific instruments Some ARHAB flights carry a simplified payload package called BalloonSat A typical ARHAB flight uses a standard latex weather balloon lasts around 2 3 hours and reaches 25 35 km 16 22 mi in altitude Experiments with zero pressure balloons superpressure balloons and valved latex balloons have extended flight times to more than 24 hours A zero pressure flight by the Spirit of Knoxville Balloon Program in March 2008 lasted over 40 hours and landed off the coast of Ireland over 5 400 km 3 400 mi from its launch point On December 11 2011 the California Near Space Project flight number CNSP 11 with the call sign K6RPT 11 launched a record breaking flight traveling 6 236 mi 10 036 km from San Jose California to a splashdown in the Mediterranean Sea The flight lasted 57 hours and 2 minutes It became the first successful U S transcontinental and the first successful transatlantic amateur radio high altitude balloon 19 20 21 22 Since that time a number of flights have circumnavigated the Earth using superpressure plastic film balloons 23 24 Each year in the United States the Great Plains Super Launch GPSL hosts a large gathering of ARHAB groups BEAR program edit Balloon Experiments with Amateur Radio BEAR is a series of Canadian based high altitude balloon experiments by a group of Amateur Radio operators and experimenters from Sherwood Park and Edmonton Alberta The experiments started in the year 2000 and continued with BEAR 9 in 2012 reaching 36 010 km 22 376 mi 25 26 The balloons are made of latex filled with either helium or hydrogen All of the BEAR payloads carry a tracking system comprising a GPS receiver an APRS encoder and a radio transmitter module Other experimental payload modules include an Amateur Radio crossband repeater and a digital camera all of which is contained within an insulated foam box suspended below the balloon BalloonSat edit nbsp Image of five BalloonSats shortly after launch on an ARHAB flight A BalloonSat is a simple package designed to carry lightweight experiments into near space 27 They are a popular introduction to engineering principles in some high school and college courses BalloonSats are carried as secondary payloads on ARHAB flights One reason BalloonSats are simple is that they do not require the inclusion of tracking equipment as secondary payloads they already are being carried by tracking capsules Space Grant started the BalloonSat program in August 2000 It was created as a hands on way to introduce new science and engineering students interested in space studies to some fundamental engineering techniques team working skills and the basics of space and Earth science The BalloonSat program is part of a course taught by Space Grant at the University of Colorado at Boulder 28 Often the design of a BalloonSat is under weight and volume constraints This encourages good engineering practices introduces a challenge and allows for the inclusion of many BalloonSats on an ARHAB flight The airframe material is usually Styrofoam or Foamcore as they are lightweight easy to machine and provide reasonably good insulation Most carry sensors data loggers and small cameras operated by timer circuits Popular sensors include air temperature relative humidity tilt and acceleration Experiments carried inside BalloonSats have included such things as captive insects and food items Before launch most BalloonSats are required to undergo testing These tests are designed to ensure the BalloonSat will function properly and return science results The tests include a cold soak drop test function test and weighing The cold soak test simulates the intense cold temperatures the BalloonSat will experience during its mission A launch and landing can be traumatic therefore the drop test requires the BalloonSat to hold together and still function after an abrupt drop The function test verifies the BalloonSat crew can prepare the BalloonSat at the launch site Variety payloads edit Besides conducting scientific activities schools influencers and other individuals have launched a wide variety of novelty payloads to the stratosphere with high altitude balloons These have included teddy bears 29 LEGO figurines 30 31 hamburgers 31 pizza 32 33 34 Cornish pasties 35 garlic bread 36 bacon and cans of beer 31 Japanese electronics manufacturer Toshiba attempted to record an advertisement in near space with an armchair and cameras tethered to a high altitude balloon 31 Geostationary balloon satellite editSee also Geostationary satellite Atmospheric satellite and Solar powered aircraft nbsp Stratobus airship nbsp Geostationary balloon satellite nbsp Geostationary airship satellite nbsp High altitude airship satellite Geostationary balloon satellites GBS are proposed high altitude balloons that would float in the mid stratosphere 60 000 to 70 000 feet 18 to 21 km above sea level at a fixed point over the Earth s surface and thereby act as an atmospheric satellite At those altitudes air density is around 1 15 to 1 20 37 of what it is at sea level The average wind speed at these levels is less than that at the surface 37 38 A propulsion system would allow the balloon to move into and maintain its position The GBS would be powered with solar panels A GBS could be used to provide broadband Internet access over a large area Laser broadband would connect the GBS to the network which could then provide a large area of coverage because of its wider line of sight over the curvature of the Earth and unimpeded Fresnel zone 39 40 41 Arizona space balloon port edit World View Enterprises built and operates a balloon spaceport high altitude balloon port in Pima County Arizona 42 See also editAerial photography ARCADE Atmospheric satellite BRRISON Columbia Scientific Balloon Facility Flight endurance record Geostationary satellite High altitude platform station Internet org Project Loon Tethered blimp World View Enterprises PongSat List of tallest structures in the United States by height Zero pressure balloons Superpressure balloon StratEx Space Dive Red Bull Stratos Nuclear electromagnetic pulse List of high altitude object events in 2023References edit ISAS 超薄膜高高度気球 BS13 08 が無人気球到達高度の世界記録を更新 トピックス Ultra thin film high altitude balloon BS13 08 breaks the world record for altitude reached by an unmanned balloon Institute of Space and Astronautical Science Japan Aerospace Exploration Agency in Japanese 2013 09 20 Archived from the original on 2023 03 06 Retrieved 2023 12 03 Sanz Fernandez de Cordoba Dr S 2004 06 24 The 100 km Boundary for Astronautics Federation aeronautique internationale Retrieved 28 December 2020 a b DIY balloon sent up 30km Boing Boing 26 October 2007 Retrieved 2008 06 08 a b McDermott Vincent 8 August 2011 Space race for DIYers National Post Archived from the original on 2013 02 28 Retrieved 2011 12 28 G Pfotzer History of the use of Balloons in Scientific Experiments Space Science Reviews 13 2 pp 200 1972 Recovered on 11 February 2009 a b Lopez Urdiales Jose Mariano October 19 2002 The Role of Balloons in the Future Development of Space Tourism PDF Houston Texas Archived from the original PDF on 13 July 2015 Retrieved 13 July 2015 Levy Steven June 14 2013 How Google Will Use High Flying Balloons to Deliver Internet to the Hinterlands Wired Betancourt Mark July 2015 See The World From 100 000 Feet Air amp Space Retrieved 9 July 2015 Wall M 2014 World View to Loft Experiments on Balloon Test Flights This Year Space com Retrieved from http www space com 26658 world view balloon research flights html Civil Aviation Safety Regulations Subpart 101 E Unmanned free balloons Australian Government Civil Aviation Safety Authority 1998 Code of Federal Regulations Title 14 Chap I SubChap F Part 101 U S Government Publishing Office 2020 We Sent Garlic Bread to the Edge of Space Then Ate It Retrieved 2022 11 20 via YouTube GSBC What is a High Altitude Balloon Archived 2017 07 22 at the Wayback Machine Retrieved August 8 2016 MoCRiS Moon Imaged from the MoCRiS Payload Earth Science Picture of the Day EPOD June 25 2019 UKHAS A Beginners Guide to High Altitude Ballooning Archived 2016 07 29 at the Wayback Machine Retrieved August 8 2016 Sobester Andras Czerski Helen Zapponi Niccolo Castro Ian 2014 04 01 High Altitude Gas Balloon Trajectory Prediction A Monte Carlo Model AIAA Journal 52 4 832 842 Bibcode 2014AIAAJ 52 832S doi 10 2514 1 J052900 ISSN 0001 1452 Amateur Radio Astronomy and weather reporting 06 Dezember 1964 Erster Ballonstart mit Amateurfunk Last in der DDR Archived 2016 08 12 at the Wayback Machine in German accessed August 8 2016 Amateur Radio Balloon Flight Crosses Atlantic Sets Records American Radio Relay League 2011 12 15 Retrieved 2011 12 15 Fernandez Lisa 2011 12 15 Two Silicon Valley high altitude ballooning groups vie for record San Jose Mercury News Retrieved 2011 12 15 Boyle Rebecca 2011 12 15 Amateur Radio Balloon Flies From California to Algeria Popular Science Retrieved 2011 12 15 Meadows Ron 2011 12 12 CNSP 11 K6RPT 11 Flight information California Near Space Project Retrieved 2011 12 15 Balloons Carrying Amateur Radio Payloads Still Circling the Earth www arrl org Party Balloon Carrying Ham Radio Payload Circles Southern Hemisphere a Second Time arrl org Tousley Nancy 1 March 2012 Kevin Schmidt High Hopes Canadian Art Archived from the original on 1 May 2015 Retrieved 8 August 2016 Sloan Barry BEAR Home Page Retrieved 19 May 2013 Exporer Scouts 632 BalloonSat slide show PDF Archived from the original PDF on 2008 05 17 Koehler Chris BalloonSat Missions to the Edge of Space Utah State University 16th Annual USU Conference on Small Satellites Retrieved 18 November 2015 Teddy bear jets into outer space www stuff co nz Retrieved 2024 03 07 Pultarova Tereza 2023 05 26 Watch 1 000 Lego astronauts fly near the edge of space video Space com Retrieved 2024 03 07 a b c d Smithsonian Magazine 10 Weird Things Humans Have Sent Into the Stratosphere Smithsonian Magazine Retrieved 2024 03 07 Forbes Paula 2012 09 17 Watch an Entire Pizza Survive a Trip Into Space Eater Retrieved 2024 03 07 I Sent A Slice Of Pizza To Space Then Ate It retrieved 2024 03 07 Chef Erik stuurt pizza de ruimte in en eet m daarna op jeugdjournaal nl in Dutch 2023 05 06 Retrieved 2024 03 07 Pasty sent up by schoolchildren is Cornwall s only successful space launch to date The Cornish Times 2023 01 11 Retrieved 2024 03 07 2 Hours of Unedited Garlic Bread Flight Footage retrieved 2024 03 07 a b Limpinsel Moritz Kuo Dawei Vijh Aarohi June 2018 SMARTS Modeling of Solar Spectra at Stratospheric Altitude and Influence on Performance of Selected III V Solar Cells 2018 IEEE 7th World Conference on Photovoltaic Energy Conversion WCPEC A Joint Conference of 45th IEEE PVSC 28th PVSEC amp 34th EU PVSEC IEEE pp 3367 3373 doi 10 1109 PVSC 2018 8547665 ISBN 978 1 5386 8529 7 On an average wind speeds are minimum in the lower stratosphere around 20 km altitude Air density at 20 km is roughly 1 20 that at sea level Boccia Luigi Pace Pasquale Amendola Giandomenico Di Massa Giuseppe July 2008 Low multipath antennas for GNSS based attitude determination systems applied to high altitude platforms GPS Solutions 12 3 163 171 Bibcode 2008GPSS 12 163B doi 10 1007 s10291 007 0075 7 ISSN 1080 5370 Average wind speed in the stratosphere is minimal at altitudes of about 20 km Values vary with season and location Source National Weather Service NWS Izet Unsalan Kunsel Unsalan Deniz 2011 A low cost alternative for satellites tethered ultra high altitude balloons Proceedings of 5th International Conference on Recent Advances in Space Technologies RAST2011 ieeexplore ieee org pp 13 16 doi 10 1109 RAST 2011 5966806 ISBN 978 1 4244 9617 4 S2CID 26712889 Zee Chong Hung 1989 04 30 The Use of Balloons for Physics and Astronomy Springer ISBN 9789027726360 Retrieved 24 March 2014 NOAA s Geostationary and Polar Orbiting Weather Satellites noaasis noaa gov Archived from the original on 25 August 2018 Retrieved 24 March 2014 Emily Calandrelli January 19 2016 Arizona Votes To Build Spaceport For Space Ballooning nbsp Wikimedia Commons has media related to Research balloons External links editSpacenear us Tracker display of current balloon launches archived 26 December 2008 NASA Goddard Space Flight Library Balloon technology collection archived 13 February 2013 StratoCat Stratospheric balloons History and present of their use in the fields of science military and aerospace Near Space book at Parallax com archived 12 October 2008 California Near Space Project Silicon Valley based ARHAB group with first successful transatlantic balloon Stratofox Aerospace Tracking Team tracking team for CNSP and other balloons and rockets archived 12 February 2003 Retrieved from https en wikipedia org w index php title High altitude balloon amp oldid 1213744719 Geostationary balloon satellite, wikipedia, wiki, book, books, library,

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