Everything about The International Space Station totally explained
The
International Space Station (
ISS) is a research facility currently being
assembled in
space. The on-orbit assembly of ISS began in 1998. The
space station is in a
low Earth orbit and
can be seen from Earth with the
naked eye: it has an altitude of approximately 350 km (217 mi) The
Brazilian Space Agency (AEB,
Brazil) participates through a separate contract with NASA. The
Italian Space Agency similarly has separate contracts for various activities not done in the framework of ESA's ISS works (where
Italy also fully participates).
China has reportedly expressed interest in the project, especially if it's able to work with the
RKA, though the Chinese are currently not involved. Early crew members all came from the Russian and U.S. space programs. German ESA astronaut
Thomas Reiter joined the
Expedition 13 crew in July 2006, becoming the first crew member from another
space agency. The station has, however, been visited by
astronauts from 16 countries. The ISS was also the destination of the first five
space tourists.
The station is serviced primarily by Russian
Soyuz and
Progress spacecraft and by U.S.
Space Shuttle orbiters. On March 9, 2008, the European Space Agency
ESA launched an
Ariane 5 with the first
Jules Verne ATV Automated Transfer Vehicle toward the ISS carrying over 8,000 kilograms of cargo. Successful docking took place at 1440 GMT on 3 April 2008.
At an estimated cost of €100 billion (~$156 billion) for the ISS project from its start until the program will end in 2017,
Origins
In the early 1980s, NASA planned
Space Station Freedom as a counterpart to the Soviet
Salyut and
Mir space stations. It never left the drawing board and, with the end of the
Soviet Union and the
Cold War, it was cancelled. The end of the
space race prompted the U.S. administration officials to start negotiations with international partners Europe, Russia, Japan and Canada in the early 1990s in order to build a truly international space station. This project was first announced in 1993 and was called Space Station Alpha. It was planned to combine the proposed space stations of all participating space agencies: NASA's
Space Station Freedom, Russia's
Mir-2 (the successor to the
Mir Space Station, the core of which is now
Zvezda) and
ESA's
Columbus that was planned to be a stand-alone spacelab.
The first section, the
Zarya Functional Cargo Block, was put in orbit in November 1998 on a Russian
Proton rocket. Two further pieces (the
Unity Module and
Zvezda service module) were added before the first crew,
Expedition 1, was sent.
Expedition 1 docked to the ISS on
November 2,
2000, and consisted of two Russian cosmonauts,
Yuri Gidzenko and
Sergei Krikalev, and U.S.
astronaut William Shepherd.
Assembly
assembly of the International Space Station is a major aerospace engineering endeavor. When assembly is complete the ISS will have a pressurized volume of approximately 1,000 cubic meters. Assembly began in November 1998 with the launch of
Zarya -- the first ISS module -- on a
Proton rocket, and as of March 2008 assembly is about 70% complete.
Two weeks after Zarya was launched, the STS-88 shuttle mission followed, bringing Unity, the first of three node modules, and connecting it to Zarya. This bare 2-module core of the ISS remained unmanned for the next one and a half years, until in July 2000 the Russian module Zvezda was added, allowing a maximum crew of three astronauts or cosmonauts to be on the ISS permanently
.
Pressurized modules
The ISS is currently under construction, and will eventually consist of fourteen pressurized modules with a combined volume of around 1,000 cubic metres. These modules include laboratories, docking compartments, airlocks, nodes and living quarters, nine of which are already in orbit, with the remaining five awaiting launch on the ground. Each module is launched either by
Space Shuttle,
Proton rocket or
Soyuz rocket, and is listed below along with its purpose, launch date and mass.
| For more information about the modules, visit the module pages linked on the table below. |
| Module |
Launch date |
Launch vehicle |
Docking date |
Mass |
Assembly flight |
Purpose |
Isolated View |
Station View |
Zarya
(FGB) |
1998-11-20 |
Proton-K |
N/A |
|
1A/R |
Provided electrical power, storage, propulsion, and guidance during initial assembly, now serves as a storage module (both inside the pressurized section and in the externally mounted fuel tanks). |
|
|
Unity
(Node 1) |
1998-12-04 |
Space Shuttle Endeavour, STS-88 |
1998-12-07 |
|
2A |
First American node, connecting the American section of the station to the Russian section (via PMA-1). Provides berthing locations for the Z0 truss, Quest airlock, Destiny laboratory and Node 3. |
|
|
Zvezda
(Service Module) |
2000-07-12 |
Proton-K |
2000-07-26 |
|
1R |
Station service module, providing main living quarters for resident crews, environmental systems and attitude & orbit control, in addition to docking locations for Soyuz spacecraft, Progress spacecraft and the Automated Transfer Vehicle. The addition of the module rendered the ISS permanently habitable for the first time. |
|
|
Destiny
(US Laboratory) |
2001-02-07 |
Space Shuttle Atlantis, STS-98 |
2001-02-10 |
|
5A |
Primary research facility for American payloads aboard the ISS, also providing environmental systems and living quarters to the station. |
|
|
Quest
(Joint Airlock) |
2001-07-12 |
Space Shuttle Atlantis, STS-104 |
2001-07-14 |
|
7A |
Primary airlock for the ISS, hosting spacewalks with both American EMU and Russian Orlan spacesuits. |
|
|
Pirs
(Docking Compartment) |
2001-09-14 |
Soyuz-U |
2001-09-16 |
|
4R |
Provides the ISS with additional docking ports for Soyuz & Progress spacecraft, and allows egress and ingress for spacewalks by cosmonauts using Russian Orlan spacesuits, in addition to providing storage space for these spacesuits. |
|
|
Harmony
(Node 2) |
2007-10-23 |
Space Shuttle Discovery, STS-120 |
2007-11-14 |
|
10A |
The "utility hub" of the ISS. Node 2 contains four racks that provide electrical power, bus electronic data, and act as a central connecting point for several other components via its six Common Berthing Mechanisms (CBMs). The European Columbus is currently berthed to Harmony. The Japanese Kibō laboratories will also be berthed to Harmony when it's launched. In addition, the Harmony module serves as a berthing port for the Multi-Purpose Logistics Modules during space shuttle logistics flights. |
|
|
Columbus
(European Laboratory) |
2008-02-07 |
Space Shuttle Atlantis, STS-122 |
2008-02-11 |
|
1E |
Primary research facility for European payloads aboard the ISS, providing ten International Standard Payload Racks and mounting locations for external experiments. |
|
|
Experiment Logistics Module
(JEM-ELM) |
2008-03-11 |
Space Shuttle Endeavour, STS-123 |
2008-03-12 |
|
1J/A |
Part of the Kibō Japanese Experiment Module laboratory, the ELM provides storage and transportation facilities to the laboratory, with a pressurized section to serve internal payloads and an unpressurized section to serve external payloads. |
|
|
|
Japanese Pressurized Module
(JEM-PM) |
2008-05-31 |
Space Shuttle Discovery, STS-124 |
TBD |
|
1J |
Not yet launched. Part of the Kibō Japanese Experiment Module laboratory, the PM is the core module of Kibō to which the ELM & Exposed Facility are berthed and contains ten International Standard Payload Racks. |
|
|
| Multipurpose Laboratory Module |
December 2008 |
Proton-K |
TBD |
|
3R |
Not yet launched. The MLM will be Russia's primary research module as part of the ISS, and will be used for experiments, docking and cargo logistics. It will also serve as a crew work and rest area, and will also be equipped with a backup attitude control system that can be used to control the station's attitude. |
|
|
| Mini-Research Module 2 |
2009-08-15 |
Soyuz-U |
TBD |
|
5R |
Not yet launched. The newest Russian component of the ISS, MRM2 will likely be used for docking and cargo storage aboard the station. |
|
|
| Mini-Research Module 1 |
2010 |
Space Shuttle Endeavour, STS-131 |
TBD |
|
ULF4 |
Not yet launched. MRM1 will be used for docking and cargo storage aboard the station. |
|
|
| Node 3 |
2010 |
Space Shuttle Discovery, STS-132 |
TBD |
|
20A |
Not yet launched. The last of the station's US nodes, Node 3 will contain an advanced life support system to recycle waste water for crew use and generate oxygen for the crew to breathe. The node also provides four berthing locations for more attached pressurized modules or crew transportation vehicles, in addition to the permanent berthing location for the station's Cupola. |
|
|
| Cupola |
2010 |
Space Shuttle Discovery, STS-132 |
TBD |
|
20A |
Not yet launched. The Cupola is an observatory module that will provide ISS crew members with a direct view of robotic operations and docked spacecraft, as well as an observation point for watching the Earth. The module will come equipped with robotic workstations for operating the SSRMS and shutters to prevent its windows from being damaged by micrometeorites. |
|
|
Major ISS systems
Power supply
The source of
electrical power for the ISS is the
sun: light is converted into electricity through the use of
solar panels. Before assembly flight 4A (shuttle mission
STS-97,
November 30,
2000) the only power source was the Russian solar panels attached to the
Zarya and
Zvezda modules: the Russian segment of the station uses 28
volts
dc (so does the
Shuttle). In the rest of the station, electricity is provided by the solar cells attached to the truss at a
voltage ranging from 130 to 180 volts dc. The power is then stabilized and distributed at 160 volts dc and then converted to the user-required 124 volts dc. Power can be shared between the two segments of the station using converters, and this feature is essential since the cancellation of the Russian
Science Power Platform: the Russian segment will depend on the U.S. built solar arrays for power supply.
Using a
high-voltage (130 to 160 volts) distribution line in the U.S. part of the station led to smaller power lines and thus weight savings.
The solar array normally tracks the sun to maximize the amount of solar power. The array is about 375 m² in area and long. In the fully-complete configuration, the solar arrays track the sun in each orbit by rotating the
alpha gimbal; while the
beta gimbal adjusts for the angle of the sun from the orbital plane. (However, until the
main truss structure was brought up, the arrays were in a temporary position perpendicular to the final orientation, and in this configuration, as shown in the image to the right, the beta gimbal was used for the main solar tracking.) Another slightly different tracking option,
Night Glider mode, can be used to reduce the drag slightly by orienting the solar arrays edgewise to the velocity vector.
Life support
The ISS
Environmental Control and Life Support System provides or controls elements such as atmospheric pressure, oxygen levels, water, and fire extinguishing, among other things. The
Elektron system generates oxygen aboard the station. The highest priority for the life support system is the ISS atmosphere, but the system also collects, processes, and stores waste and water produced and used by the crew. For example, the system recycles fluid from the sink, shower, urine, and condensation.
Activated charcoal filters are the primary method for removing byproducts of human metabolism from the air.
Attitude control
The attitude (orientation) of the station is maintained by either of two mechanisms. Normally, a system using several
control moment gyroscopes (CMGs) keeps the station oriented, for example with
Destiny forward of
Unity, the P truss on the port side and
Pirs on the earth-facing (nadir) side. When the CMG system becomes saturated, it can lose its ability to control station attitude. In this event, the Russian Attitude Control System is designed to take over automatically, using thrusters to maintain station attitude and allowing the CMG system to desaturate. This happened during
Expedition 10. When a shuttle orbiter is docked to the station, it can also be used to maintain station attitude. This procedure was used during
STS-117 as the S3/S4 truss was being installed.
Altitude control
The ISS is maintained at an orbit from a minimum altitude limit of 278 km to a maximum limit of 460 km. The normal maximum limit is 425 km to allow Soyuz rendezvous missions. Because ISS is constantly falling due to minute
atmospheric drag and
gravity gradient effects, it needs to be boosted to a higher altitude several times each year. A graph of altitude over time shows that it drifts down almost 2.5 km per month. The boosting can be performed by two boosters on the
Zvezda module, a docked Space Shuttle, a
Progress resupply vessel or by ESA's
ATV and takes approximately two orbits (three hours) in which it's boosted several kilometers higher. The
2005 NASA Authorization Act designated the U.S segment of the International Space Station as a national laboratory with a goal to increase the utilization of the ISS by other Federal entities and the private sector. As of 2007, little experimentation other than the study of the long-term effects of microgravity on humans has taken place. With four new research modules set to arrive at the ISS by 2010, however, more specialized research is expected to begin.
Scientific ISS modules
The
Destiny Laboratory Module is the main research facility currently aboard the ISS. Produced by
NASA and launched in February 2001, it's a research facility for general experiments. The
Columbus module is another research facility, designed by the
ESA for the ISS. Its purpose is to facilitate scientific experiments and was launched on February 2008. It should provide a
generic laboratory as well as ones specifically designed for
biology,
biomedical research and
fluid physics. There are also a number of planned expansions that will be implemented to study
quantum physics and
cosmology. The
Japanese Experiment Module, also known as
Kibō, is scheduled to be in space after the
STS-127 launch in or around January, 2009. It is being developed by
JAXA in order to function as an observatory and to measure various astronomical data. The
ExPRESS Logistics Carrier, developed by
NASA, is set to be launched for the ISS with the
STS-129 mission, which is expected to take place no earlier than
September 11,
2009. It will allow experiments to be deployed and conducted in the vacuum of space and will provide the necessary electricity and computing to locally process data from experiments. The
Multipurpose Laboratory Module, created by the
RKA, is expected to launch for the ISS in late 2009. It will supply the proper resources for general microgravity experiments.
A couple of planned research modules have been cancelled, including the
Centrifuge Accommodations Module (used to produce varying levels of
artificial gravity) and the
Russian Research Module (used for general experimentation). Several planned experiments, such as the
Alpha Magnetic Spectrometer, have been cancelled as well.
Areas of research
There are a number of plans to study biology on the ISS. One goal is to improve understanding of the effect of long-term space exposure on the human body. Subjects such as
muscle atrophy,
bone loss, and fluid shifts are studied with the intention to utilize this data so
space colonization and lengthy
space travel can become feasible. The effect of near-weightlessness on
evolution, development and growth, and the internal processes of plants and animals are also studied. In response to recent data suggesting that microgravity enables the growth of three-dimensional human body-like tissues and that unusual protein crystals can be formed in space, NASA has indicated a desire to investigate these phenomena.
On
November 2 2006 the payload brought by the Russian
Progress M-58 allowed the crew to repair the Elektron using spare parts.
2007 – Computer failure
On
June 14 2007 during
Expedition 15 and flight day 7 of
STS-117's visit to ISS, a computer malfunction on the Russian segments at 06:30 UTC left the station without thrusters, oxygen generation, carbon dioxide scrubber, and other environmental control systems, and caused the temperature on the station to rise. A successful restart of the computers resulted in a false fire alarm that woke the crew at 11:43 UTC. The two computer systems (command and navigation) are each composed of three computers. Each computer is referred to as a "lane". NASA reported that without the computer that controls the oxygen levels, the station had 56 days of oxygen available.
By the afternoon of
June 16, ISS Program Manager
Michael Suffredini confirmed that all six computers governing command and navigation systems for Russian segments of the station, including two thought to have failed, were back online, and would be tested over several days. The cooling system was the first system brought back online. NASA suggested that the overcurrent protection circuits designed to safeguard each computer from power spikes were at fault, and may have been tripped due to increased interference, or "noise," from the station's plasma environment related to the addition of the new
starboard trusses and solar arrays. This was initially a concern, because the
European Space Agency uses the same computer systems, supplied by EADS
Astrium Space Transportation, for the
Columbus Laboratory Module and the
Automated Transfer Vehicle. Once the root cause was understood, plans were implemented to avoid the problem in the future.
2007 – Torn solar panel
On
October 30,
2007 during
Expedition 16 and flight day 7 of
STS-120's visit to ISS, following the reposition of the P6 truss segment, ISS and
Space Shuttle Discovery crew members began the deployment of the trusses' two solar arrays. The first array deployed without incident, and the second array deployed approximately 80% before astronauts noticed a tear. The arrays had been deployed in earlier phases of the space station's construction, and the retraction necessary to move the truss to its final position had gone less smoothly than planned.
A second, smaller tear was noticed upon further inspection, and the mission's planned spacewalks were completely replanned in mere days to devise a repair. On Saturday
November 3, spacewalker
Scott Parazynski assisted by
Douglas Wheelock fixed the torn panels using makeshift "cufflinks" and riding on the end of the space shuttle's boom inspection arm; the first ever spacewalker to do so. The spacewalk was regarded as significantly more dangerous than most due to the possibility of shock from the electricity generating solar arrays, the unprecedented usage of the shuttle boom arm, and the lack of spacewalk planning and training for the impromptu procedure. Parazynski was, however, able to repair the damage as planned and the repaired array was fully deployed.
2007 – Damaged starboard Solar Alpha Rotary Joint
The starboard Solar Alpha Rotary Joint (SARJ) malfunctioned during the
STS-120 mission. This and the port SARJ rotate the large solar arrays to keep them facing the Sun while the ISS's main body axis remains horizontal, pointing forward in the direction of orbital motion. Excessive vibration and high current spikes in the array drive motor resulted in a decision to substantially curtail motion of the starboard SARJ until the cause is understood. Inspections during EVAs have shown metallic shavings and debris in the large drive gear.
As of the
STS-123 mission, the cause is still not fully understood, and therefore no permanent fix has been identified.
The station appears to have sufficient operating power to carry out its near-term science program with only modest impact on operations.
On 30 January 2008, NASA believes the problem was rectified with the replacement of the Bearing Motor Roll Ring Module (BMRRM) in BGA 1A.
Visiting spacecraft
Planned
Japanese (JAXA) H-II Transfer Vehicle (HTV) resupply vehicle for Kibo module (scheduled for 2009)
American (NASA) Orion for possible crew rotation and as resupply transporter (officially scheduled for 2014)
Proposed
SpaceX Dragon for NASA Commercial Orbital Transportation Services (Scheduled for 2009)
Russian (Roskosmos) Space Shuttle Kliper for possible crew rotation and as resupply transporter (scheduled for 2012)
European-Russian Crew Space Transportation System (Soyuz-derived) crew rotation and resupply spacecraft (scheduled for 2014)
An additional spacecraft, the K-1 Vehicle manufactured by Rocketplane Kistler, was proposed as part of the NASA Commercial Orbital Transportation Services program, and was scheduled to fly in 2009. On October 18 2007, NASA discontinued its agreement with Rocketplane Kistler after the company couldn't secure further financing and didn't meet a critical design review for the pressurized cargo module. NASA then announced that the remaining $175 million commitment to the project would be made available to other companies. On 19 February 2008, NASA awarded Orbital Sciences Corporation with the remaining $170 million to develop its Cygnus spacecraft for the COTS program.
Expeditions
All permanent station crews are named, where n is sequentially increased after each expedition. Expeditions have an average duration of half a year and are often considered synonymous with "Increments." However, "Increments" are distinguished from Expeditions as the program planning period for activities that are to occur during a particular Expedition's residence on ISS. The start of both an Expedition and an Increment is defined by the departure of the previous Expedition crew on a Soyuz spacecraft. The definition of the Increment is in flux in preparation for 6-person crews that will be broken up into 3-person crews which overlap in their 6-month missions on ISS.
The International Space Station is the most-visited spacecraft in the history of space flight. As of April 11, 2008, it has had 213 (non-distinct) visitors. Mir had 137 (non-distinct) visitors (See Space station). The number of distinct visitors of the ISS is 158 (see list of International Space Station visitors).
Legal aspects
Agreement
The legal structure that regulates the space station is multi-layered. The primary layer establishing obligations and rights between the ISS partners is the Space Station Intergovernmental Agreement (IGA), an international treaty signed on January 28 1998 by fifteen governments involved in the Space Station project. The ISS consists of the United States, Canada, Japan, the Russian Federation, and eleven Member States of the European Space Agency (Belgium, Denmark, France, Germany, Italy, The Netherlands, Norway, Spain, Sweden, Switzerland and the United Kingdom). Article 1 outlines its purpose:
This Agreement is a long term international co-operative framework on the basis of genuine partnership, for the detailed design, development, operation, and utilisation of a permanently inhabited civil Space Station for peaceful purposes, in accordance with international law.
The IGA sets the stage for a second layer of agreements between the partners referred to as 'Memoranda of Understanding' (MOUs), of which four exist between NASA and each of the four other partners. There are no MOUs between ESA, Roskosmos, CSA and JAXA due to the fact that NASA is the designated manager of the ISS. The MOUs are used to describe the roles and responsibilities of the partners in more detail.
A third layer consists of bartered contractual agreements or the trading of the partners' rights and duties, including the 2005 commercial framework agreement between NASA and Roskosmos that sets forth the terms and conditions under which NASA purchases seats on Soyuz crew transporters and cargo capacity on unmanned Progress transporters.
A fourth legal layer of agreements implements and supplements the four MOUs further. Notably among them is the ISS code of conduct, setting out criminal jurisdiction, anti-harassment and certain other behavior rules for ISS crewmembers.
Utilization
There is no fixed percentage of ownership for the whole space station. Rather, Article 5 of the IGA sets forth that each partner shall retain jurisdiction and control over the elements it registers and over personnel in or on the Space Station who are its nationals.
Giving a precise cost estimate for the ISS is, however, not straightforward; it is, for instance, hard to determine which costs should actually be attributed to the ISS program or how the Russian contribution should be measured, as the Russian space agency runs at considerably lower USD costs than the other partners.
NASA
Overview
The overall majority of costs for NASA are incurred by flight operations and expenses for the overall management of the ISS. Costs for initially building the U.S. portion of the ISS modules and external structure on the ground and construction in space as well as crew and supply flights to the ISS do account for far less than the general operating costs (see annual budget allocation below).
NASA doesn't include the basic Space Shuttle program costs in the expenses incurred for the ISS program, despite the fact that the Space Shuttle has been nearly exclusively used for ISS construction and supply flights since December 1998.
NASA's 2007 budget request lists costs for the ISS (without Shuttle costs) as $25.6 billion for the years 1994 to 2005. For each of 2005 and 2006 about $1.7 to 1.8 billion are allocated to the ISS program. The annual expenses will increase until 2010 when that'll reach $2.3 billion and should then stay at the same level, however inflation-adjusted, until 2016, the defined end of the program. NASA has allocated between $300 and 500 million for program shutdown costs in 2017.
2005 ISS budget allocation
The $1.8 billion expensed in 2005 consisted of:
Development of new hardware: $70 million were allocated to core development, for instance development of systems like navigation, data support or environmental.
Spacecraft Operations: $800 million consisting of $125 million for each of software, extravehicular activity systems, and logistics and maintenance. An additional $150 million is spent on flight, avionics and crew systems. The rest of $250 million goes to overall ISS management.
Launch and Mission operations: Although the Shuttle launch costs are not considered part of the ISS budget, mission and mission integration ($300 million), medical support ($25 million) and Shuttle launch site processing ($125 million) is within the ISS budget.
Operations Program Integration: $350 million was spent on maintaining and sustaining U.S. flight and ground hardware and software to ensure integrity of the ISS design and the continuous, safe operability.
ISS cargo/crew: $140 million was spent for purchase of supplies, cargo and crew capability for Progress and Soyuz flights.
Shuttle costs as part of ISS costs
Only costs for mission and mission integration and launch site processing for the 33 ISS-related Shuttle flights are included in NASA's ISS program costs. Basic costs of the Shuttle program are, as mentioned above, not considered part of the overall ISS costs by NASA, because the Shuttle program is considered an independent program aside from the ISS. Since December 1998 the Shuttle has, however, been used nearly exclusively for ISS flights (since the first ISS flight in December 1998, until October 2007 only 5 flights out of 28 flights have not been to the ISS, and only the planned Hubble Space Telescope servicing mission in 2008 won't be ISS-related out of 13 planned missions until the end of the Space Shuttle program in 2010).
Shuttle program costs during ISS operations from 1999 to 2005 (disregarding the first ISS flight in December 1998) have amounted to approximately $24 billion (1999: $3,028.0 million, 2000: $3,011.2 million, 2001: $3,125.7 million, 2002: $3,278.8 million, 2003: $3,252.8 million, 2004: $3,945.0 million, 2005: $4,319.2 million). In order to derive the ISS-related costs, expenses for non-ISS flights need to be subtracted, which amount to 20% of the total or about $5 billion. For the years 2006-2011 NASA projects another $20.5 billion in Space Shuttle program costs (2006: $4,777.5 million, 2007: $4,056.7 million, 2008: $4,087.3 million, 2009: $3,794.8 million, 2010: $3,651.1 million and 2011: $146.7 million). If the Hubble servicing mission is excluded from those costs, ISS-related costs will be approximately $19 billion for Shuttle flights from 2006 until 2011. In total, ISS-related Space Shuttle program costs will therefore be approximately $38 billion.
Overall ISS costs for NASA
Assuming NASA's projections of average costs of $2.5 billion from 2011 to 2016 and the end of spending money on the ISS in 2017 (about $300-500 million) after shutdown in 2016 are correct, the overall ISS project costs for NASA from the announcement of the program in 1993 to its end will be about $53 billion (25.6 billion for the years 1994-2005 and about 27 to 28 billion for the years 2006-2017).
There have also been considerable costs for designing Space Station Freedom in the 1980s and early 1990s, before the ISS program started in 1993. Plans of Space Station Freedom were reused for the International Space Station.
To sum up, although the actual costs NASA views as connected to the ISS are only half of the $100 billion figure often cited in the media, if combined with basic program costs for the Shuttle and the design of the ISS' precursor project Space Station Freedom, the costs reach $100 billion for NASA alone.
ESA
ESA calculates that its contribution over the 15 year lifetime of the project will be €9 billion. Just the costs for the Columbus Laboratory tops more than €1.4 billion (about $2.1 billion), including the money spent on the ground control infrastructure known as Columbus Control Center to operate it. The total development costs for ATV amount to approximately €1.35 billion and considering that each Ariane 5 launch costs around €150 million, each ATV launch will incur considerable costs as well.
JAXA
The development of the Japanese Experiment Module, JAXA's main contribution to the ISS, has cost about 325 billion yen (about $2.8 billion). In the year 2005, JAXA allocated about 40 billion yen (about 350 million USD) to the ISS program. The annual running costs for Japanese Experiment Module will total around $350 to 400 million. In addition JAXA has committed itself to develop and launch the H-II Transfer Vehicle, for which development costs total nearly $1 billion. In total, over the 24 year lifespan of the ISS program, JAXA will contribute well over $10 billion to the ISS program.
Roskosmos
A considerable part of the Russian Space Agency's budget is used for the ISS. Since 1998 there have been over two dozen Soyuz and Progress flights, the primary crew and cargo transporters since 2003. The question of how much Russia spends on the station (measured in USD), is, however, not easy to answer. The two modules currently in orbit are derivatives of the Mir program and therefore development costs are much lower than for other modules. In addition, the exchange rate between ruble and USD isn't adequately giving a real comparison to what the costs for Russia really are.
CSA
Canada, whose three main contributions to the ISS are the Canadarm2, the mobile base system, and Dextre (the Special Purpose Dexterous Manipulator, also known as the Canada Hand), estimates that through the last 20 years it has contributed about C$1.4 billion to the ISS. Canada has continued to be a vital member of ISS through the past ten years and continues to play a major role in the ISS.
Criticism
The ISS and NASA have been the targets of varied criticism over the years. Critics contend that the time and money spent on the ISS could be better spent on other projects—whether they be robotic spacecraft missions, space exploration, investigations of problems here on Earth, or just tax savings. Some critics, like Robert L. Park, argue that very little scientific research was convincingly planned for the ISS in the first place. They also argue that the primary feature of a space-based laboratory is its microgravity environment, which can usually be studied more cheaply with a "vomit comet" (that is, an aircraft which flies in parabolic arcs.)
Two of the most ambitious ISS projects to date—the Alpha Magnetic Spectrometer and the Centrifuge Accommodations Module—have been cancelled or delayed due to the prohibitive costs NASA faces in simply completing the ISS. As a result, the research done on the ISS is generally limited to experiments which don't require any specialized apparatus. For example, in the first half of 2007, ISS research dealt primarily with human biological responses to being in space, covering topics like kidney stones, circadian rhythm, and the effects of cosmic rays on the nervous system. Critics argue that this research has little practical value, since space exploration is today almost universally done by robots.
Other critics have attacked the ISS on some technical design grounds:
Jeff Foust argued that the ISS requires too much maintenance, especially by risky, expensive EVAs;
The Astronomical Society of the Pacific has mentioned that its orbit is rather highly inclined, which makes Russian launches cheaper, but US launches more expensive. This was intended as a design point, to encourage Russian involvement with the ISS—and Russian involvement saved the project from abandonment in the wake of the Space Shuttle Columbia disaster—but the choice may have increased the costs of completing the ISS substantially.
In response to some of these criticisms, advocates of manned space exploration say that criticism of the ISS project is short-sighted, and that manned space research and exploration have produced billions of dollars' worth of tangible benefits to people on Earth. Jerome Schnee estimated that the indirect economic return from spin-offs of human space exploration has been many times the initial public investment. A review of the claims by the Federation of American Scientists argued that NASA's rate of return from spin-offs is actually very low, except for aeronautics work that has led to aircraft sales.
Critics also say that NASA is often casually credited with "spin-offs" (such as Velcro and portable computers) that were developed independently for other reasons. NASA maintains a list of spin-offs from the construction of the ISS, as well as from work performed on the ISS. However, NASA's official list is much narrower and more arcane than dramatic narratives of billions of dollars of spin-offs.
It is therefore debatable whether the ISS, as distinct from the wider space program, will be a major contributor to society. Some advocates argue that apart from its scientific value, it's an important example of international cooperation. Others claim that the ISS is an asset that, if properly leveraged, could allow more economical manned Lunar and Mars missions. Either way, advocates argue that it misses the point to expect a hard financial return from the ISS; rather, it's intended as part of a general expansion of spaceflight capabilities.
Sightings
Due to the size of the International Space Station, which is the size of an American football field, and particularly due to the large reflective area offered by its solar panels, ground based observation of the station is possible with the naked eye if one is within 63 degrees latitude. In many cases the station is one of the brightest naked-eye objects in the sky, though it's only visible for brief periods of time. This is because the station is in low earth orbit, and the sun angle and observer locations need to coincide.
NASA provides data on forthcoming opportunities for viewing the ISS (and other objects) on the Station Sightings
web page, as do the European Space Agency and the independent site Heavens-Above.
Miscellany
Space tourism and a wedding
As of 2007 there have been five space tourists to the ISS, each spending around US $25 million; they all went there aboard Russian supply missions. There has also been a space wedding when cosmonaut Yuri Malenchenko on the station married Ekaterina Dmitrieva, who was in Texas.
ISS golf event
Golf Shot Around The World was an event in which, on an EVA, a special golf ball, equipped with a tracking device, was hit from the station and sent into its own low Earth orbit for a fee paid by a Canadian golf equipment manufacturer to the Russian Space Agency. The task was supposed to be performed on Expedition 13, but the event was postponed, and took place on Expedition 14.
Microgravity
At the station's orbital altitude, the gravity from the Earth is 88% of that at sea level. The state of weightlessness is due to the constant free fall of the ISS, which according to the equivalence principle, is indiscernible from being in a state of zero gravity. The environment on the station is often described as microgravity, due to four effects:
The drag resulting from the residual atmosphere.
Vibratory acceleration due to mechanical systems and the crew on board the ISS.
Orbital corrections by the on-board gyroscopes (or thrusters).
The spatial separation from the real center of mass of the ISS, with a level of gravity on the order of 2 to 1,000 millionths of one g (the value varies with the frequency of the disturbance, with the low value occurring at frequencies below 0.1 Hz, and the higher value at frequencies of 100 Hz or more).
Time zone
The ISS uses Coordinated Universal Time (UTC, sometimes informally called GMT) to regulate its onboard day. This is roughly equidistant between its two control centres in Houston and Moscow. The windows are covered at "night" to give the impression of darkness since it experiences 16 sunrises/sunsets a day. The crew typically wakes up at around 7:00 UTC; they work for about ten hours each weekday and five hours each Saturday. During visiting shuttle missions, the ISS crew will mostly follow the shuttle's Mission Elapsed Time (MET), which is a flexible timezone based solely on the launchtime of the shuttle mission. Because the sleeping periods between the UTC timezone and the MET usually differ, the ISS crew often has to adjust their sleeping pattern before the shuttle arrives and after it leaves to shift from one timezone to the other, therefore this is called sleepshifting.
Atmosphere
The atmosphere on board the ISS is maintained to have a composition similar to that of the Earth's atmosphere. Normal air pressure on the Space Station is 101.3 kPa (14.7 psi), the same as at sea level on Earth. This doesn't match the atmosphere on the shuttle, so adjustments are performed during visits.
Further Information
Get more info on 'International Space Station'.
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