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United States Government Accountability Office: 
GAO: 

Testimony: 

Before the Committee on Science, Space, and Technology, House of 
Representatives: 

For Release on Delivery: 
Expected at 9:30 a.m. EDT:
Wednesday, March 28, 2012: 

NASA: 

Significant Challenges Remain for Access, Use, and Sustainment of the 
International Space Station: 

Statement of Cristina T. Chaplain, Director: Acquisition and Sourcing 
Management: 

GAO-12-587T: 

GAO Highlights: 

Highlights of GAO-12-587T, a testimony before the Committee on 
Science, Space, and Technology, House of Representatives. 

Why GAO Did This Study: 

Construction of the International Space Station (ISS) required 
dedication and effort on the part of many nations to be successful. 
Further, the funding necessary to accomplish this task was 
significant, with the United States alone directly investing nearly 
$50 billion in its development. As construction of the on-orbit 
laboratory is complete, now is the time for the United States and its 
partners to make use of this investment and recently, Congress took 
steps to extend the life of the ISS until at least 2020. 

GAO has cautioned for years that NASA should ensure it has a 
capability to access and utilize the space station following 
retirement of the space shuttle in 2011. We have highlighted the 
challenges associated with transporting cargo and crew to and from the 
ISS, as well as the difficulties NASA faces in ensuring the ISS 
supports its purpose of scientific research and in safely operating 
the station. Some risks have been realized. For example, commercial 
vehicles are significantly behind schedule—-with the first launch to 
the space station planned for 2012. 

GAO's statement today will focus on the progress NASA has made and the 
challenges the agency faces in accessing, ensuring full utilization 
of, and sustaining the ISS. To prepare this statement, GAO relied on 
prior relevant work on the ISS and NASA's commercial cargo and crew 
efforts and conducted a limited amount of additional work to update 
planned flight information. 

What GAO Found: 

NASA plans to use international partner and new domestic commercial 
launch vehicles to access, utilize, and sustain the International 
Space Station from 2012 through 2020. However, the agency faces 
challenges in transporting cargo and crew to the ISS as well as 
ensuring the station is fully utilized. NASA’s decision to rely on the 
new commercial vehicles to transport cargo starting in 2012 and to 
transport crew starting in 2017 is inherently risky because the 
vehicles are not yet proven and are experiencing delays in 
development. Further, NASA does not have agreements in place for 
international partners to provide cargo services to the ISS beyond 
2016. The agency will also face a decision regarding the need to 
purchase additional seats on the Russian Soyuz vehicle beyond 2016, 
likely before commercial vehicles have made significant progress in 
development, given the three-year lead time necessary for acquiring a 
seat. This decision is further complicated because restrictions 
prohibit NASA from making certain payments to Russia in connection 
with the ISS unless the President makes a determination. Further, NASA 
currently expects to transport all cargo needed by the ISS in 51 
flights through 2020, but if international partner agreements and 
commercial service contracts do not materialize as the agency plans 
for the years beyond 2016, the situation could lead to a potential 
cargo shortfall. 

If NASA can access the station, it will next be challenged with fully 
utilizing the ISS national laboratory for its intended purpose—
scientific research. To take steps to meet this challenge and 
consistent with a 2009 GAO recommendation, in 2011 NASA selected an 
organization to centrally oversee ISS national laboratory research 
decision-making. It is too soon, however, to determine whether this 
organization is ensuring full scientific utilization of the ISS. 
Regardless of the efforts of the management body, as GAO noted in a 
2009 report, constraints on crew time for conducting science could 
also impact full utilization. 

If NASA can overcome its challenges related to accessing the station, 
it has reasonable approaches in place for estimating spare parts and 
assessing the structural health of the space station. These approaches 
provide NASA with increased assurance that the agency will have 
sufficient spares and will put mitigations in place to effectively and 
safely utilize the space station. 

Figure: International Space Station: 

[Refer to PDF for image: photograph] 

Source: NASA. 

[End of figure] 

View [hyperlink, http://www.gao.gov/products/GAO-12-587T]. For more 
information, contact Cristina Chaplain at (202) 512-4841 or 
chaplainc@gao.gov. 

[End of section] 

Chairman Hall, Ranking Member Johnson, and Members of the Committee: 

Thank you for inviting me here today to discuss utilization of the 
International Space Station (ISS). The construction of the ISS is a 
significant technical achievement. In essence, the National 
Aeronautics and Space Administration (NASA) and its international 
partners have assembled and constructed a skyscraper-sized laboratory 
in low-earth orbit. This achievement involved dedication and effort on 
the part of all participating nations and individuals. With 
construction completed and a full crew of six astronauts on-board, the 
ISS stands poised to deliver scientific breakthroughs enabled by its 
unique capabilities. The potential of the ISS program to deliver on 
the promise of scientific discovery, however, is inextricably linked 
to NASA's ability to safely access, sustain, and fully utilize the 
laboratory in orbit. 

Now that ISS construction is finished, NASA and the ISS program face 
three major challenges, which will be the focus of my testimony. First 
and foremost, NASA must be able to transport cargo and crew to and 
from the ISS. Second, NASA must ensure that the management of the ISS 
national laboratory results in effective utilization of the station 
for its primary purpose--scientific research. Finally, NASA must 
ensure that replaceable spares are available and that the ISS is 
structurally sound and can safely continue operations. 

We have been reporting on the difficulties associated with sustaining 
the ISS in the post-space shuttle era since May 2005 when we first 
recommended that NASA take actions to determine the best available 
options for supporting the station after shuttle retirement.[Footnote 
1] In July 2006, we expressed our initial concerns regarding NASA's 
acquisition strategy for the shuttle's replacement, the human 
spaceflight system known as Constellation, because of lack of a sound 
business case based on resources that are matched to requirements, a 
stable design, and well-defined cost estimates.[Footnote 2] Since 
2008, we have cautioned that the use of international launch vehicles 
is only a back-up and a less-capable means of supporting the station, 
as well as raised concerns about the ambitious schedules for the 
vehicles being developed under NASA's Commercial Crew and Cargo 
Program.[Footnote 3] In a November 2009 report, we iterated our 
concerns that limited international partner vehicle capacity and 
potential delays in planned commercial vehicle development could 
impede efforts to maximize utilization of all ISS research 
facilities.[Footnote 4] In 2011 reports and testimony, we observed 
that commercial cargo launch development remained behind schedule and, 
even when coupled with international partner launch capacity, may not 
cover all of the ISS anticipated needs beginning in 2014.[Footnote 5] 
Further, we reported that the funding provided for NASA's commercial 
crew efforts was significantly less than expected, as other priorities 
such as the Space Launch System received increased funding. 

In preparing this statement, we relied on our prior reports and 
testimonies, including those related to NASA's management of 
commercial launch vehicle development, the agency's acquisition 
approach for commercial crew transportation, and ISS sustainment and 
utilization.[Footnote 6] We also conducted a limited amount of 
additional audit work in March 2012 to update information on planned 
commercial cargo and international partner flights. Our prior work in 
these areas, as well as the work conducted to support this statement, 
was performed in accordance with generally accepted government 
auditing standards. Those standards require that we plan and perform 
the audit to obtain sufficient and appropriate evidence to provide a 
reasonable basis for our findings and conclusions based on our audit 
objectives. We believe that the evidence obtained provides a 
reasonable basis for our findings and conclusions based on our audit 
objectives. 

Background: 

The ISS program began in 1993 with several partner countries: Canada, 
the 11 member nations of the European Space Agency, Japan, and Russia. 
From 1994 through 2010, NASA estimates that it directly invested over 
$48 billion in development and construction of the on-orbit scientific 
laboratory, the ISS. NASA intended ISS assembly to be complete much 
sooner than it was. For example, in 1995, NASA expected to ISS 
assembly to be finished by June 2002, whereas the agency actually 
completed assembly in 2010. With ISS expected to be in use only 
through 2015, this slower pace shortened the amount of time NASA had 
available to take advantage of the significant monetary investment and 
to fully utilize the station. As a result, the NASA Authorization Act 
of 2010 required the NASA Administrator to take all actions necessary 
to ensure the safe and effective operation of the ISS through at least 
September 30, 2020. [Footnote 7] 

The ISS is the largest orbiting man-made object. (See fig. 1) It is 
composed of about 1 million pounds of hardware, brought to orbit over 
the course of a decade. The ISS includes (1) primary structures, that 
is, the external trusses which serve as the backbone of the station 
and the pressurized modules that are occupied by the ISS crew, and (2) 
functional systems made up of replaceable units, that is, systems that 
provide basic functionality such as life support and electrical power 
that are made of modular components that are replaceable by astronauts 
on orbit. 

Figure 1: International Space Station: 

[Refer to PDF for image: photograph] 

Source: NASA. 

[End of figure] 

The ISS was constructed to support three activities: scientific 
research, technology development, and development of industrial 
applications. The facilities aboard the ISS allow for ongoing research 
in microgravity, studies of other aspects of the space environment, 
tests of new technology, and long-term space operations. The 
facilities also enable a permanent crew of up to six astronauts to 
maintain their physical health standards while conducting many 
different types of research, including experiments in biotechnology, 
combustion science, fluid physics, and materials science, on behalf of 
ground-based researchers. Furthermore, the ISS has the capability to 
support research on materials and other technologies to see how they 
react in the space environment. 

NASA planned for the space shuttle to serve as the means of 
transporting crew, hardware, and supplies to the ISS through the end 
of the station's life. However, in 2004, President George W. Bush 
announced his Vision for Space Exploration (Vision) that included 
direction for NASA to develop new spaceflight systems under the 
Constellation program to replace the space shuttle as NASA's primary 
spaceflight system. The Vision also included provisions for NASA to 
pursue commercial alternatives or providing transportation and other 
services to support the ISS after 2010.[Footnote 8] NASA established 
the Commercial Crew and Cargo Program in 2005 to facilitate the 
private demonstration of safe, reliable, and cost-effective 
transportation services and purchase these services commercially. When 
the Constellation program was canceled in 2010, the commercial 
vehicles became NASA's primary focus for providing cargo and crew 
transportation to the ISS. The success of commercial efforts became 
even more important in 2010 when Congress authorized the extension of 
space station operations until at least 2020 from 2015, and the 
President directed that NASA transition the role of human 
transportation to low-earth orbit to commercial space companies. 

NASA Faces Challenges Transporting Cargo and Crew to and from the ISS: 

The greatest challenge facing NASA is transporting cargo and crew to 
and from the ISS to make effective use of the ISS. NASA plans to rely 
on ISS international partner and new commercial launch vehicles to 
transport cargo and crew to and from the ISS until at least 2020. NASA 
hopes to begin using new commercial cargo vehicles in 2012 and crew 
vehicles to transport astronauts to and from the ISS beginning in 
2017. NASA's decision to rely on the new commercial vehicles is 
inherently risky because the vehicles are still in development and not 
yet proven or fully operational. 

NASA Plans to Use International Partner and Commercial Flights but 
International Agreements Are Not in Place and Commercial Vehicles 
Remain Unproven: 

NASA is relying on 51 flights of international partner and commercial 
vehicles to transport cargo to the ISS from 2012 through 2020, but 
agreements for international flights after 2016 are not in place and 
the commercial vehicles are unproven. NASA has agreements in place 
with the European and Japanese space consortiums for their respective 
vehicles--the European Automated Transfer Vehicle (ATV), and the 
Japanese H-II Transfer Vehicle (HTV)--to conduct cargo resupply 
missions beginning in 2012 through 2016. The ATV and HTV are unmanned 
vehicles that have flown to the ISS, and carry such items as hardware 
and water.[Footnote 9] NASA's current plans anticipate employing a 
total of 12 international partner launches--8 from 2012 to 2016 and 4 
from 2017 through 2020. NASA does not have agreements in place for 
international partners to provide cargo services to the ISS beyond 
2016. NASA plans to use the ATV for a number of cargo flights through 
2014, but no longer anticipates its use after that time. NASA plans to 
use HTV for a number of cargo flights through 2016, but its 
negotiations with the Japanese partners for flights beyond 2016 are in 
their infancy. 

NASA also plans to use two types of domestic commercial launch 
vehicles to maintain ISS from 2012 through 2020. Development of these 
vehicles--the Falcon 9 and Antares[Footnote 10]--was fostered under a 
NASA-initiated effort known as Commercial Orbital Transportation 
Services. These vehicles are being developed by private industry 
corporations--Falcon 9 by SpaceX and Antares by Orbital Sciences 
Corporation. In late 2008, NASA awarded contracts to both companies to 
provide cargo transport services to the ISS. Only SpaceX will be able 
to safely return significant amounts of cargo to earth, such as the 
results of scientific experiments. NASA anticipates that SpaceX will 
begin providing that capability in 2012. 

Commercial vehicles are essential to sustaining and utilizing the ISS. 
As table 1 indicates, SpaceX and Orbital are scheduled to fly 20 (71 
percent) of the 28 launches NASA plans through 2016 and follow-on 
commercial resupply vehicles are expected to fly 19 (83 percent) of 
the 23 launches from 2017 through 2020.[Footnote 11] 

Table 1: NASA's Planned Vehicle Launches for 2012 to 2020 to Resupply 
the ISS as of March 2012: 

Vehicles: 

ATV; 
2012: 1; 
2013: 1; 
2014: 1; 
2015: [Empty]; 
2016: [Empty]; 
2017: [Empty]; 
2018: [Empty]; 
2019: [Empty]; 
2020: [Empty]; 
Total: 3. 

HTV; 
2012: 1; 
2013: 1; 
2014: 1; 
2015: 1; 
2016: 1; 
2017: 1; 
2018: 1; 
2019: 1; 
2020: 1; 
Total: 9. 

SpaceX; 
2012: 2; 
2013: 2; 
2014: 2; 
2015: 3; 
2016: 3; 
2017: [Empty]; 
2018: [Empty]; 
2019: [Empty]; 
2020: [Empty]; 
Total: 12. 

Orbital; 
2012: 1; 
2013: 2; 
2014: 1; 
2015: 2; 
2016: 2; 
2017: [Empty]; 
2018: [Empty]; 
2019: [Empty]; 
2020: [Empty]; 
Total: 8. 

Follow-on commercial resupply; 
2012: [Empty]; 
2013: [Empty]; 
2014: [Empty]; 
2015: [Empty]; 
2016: [Empty]; 
2017: 5; 
2018: 5; 
2019: 5; 
2020: 4; 
Total: 19. 

Total; 
2012: 5; 
2013: 6; 
2014: 5; 
2015: 6; 
2016: 6; 
2017: 6; 
2018: 6; 
2019: 6; 
2020: 5; 
Total: 51. 

Source: GAO analysis of NASA data. 

Note: NASA does not have contracts with commercial providers or 
negotiated agreements with international partners for flights from 
2017 through 2020. 

[End of table] 

This plan relies on commercial vehicles meeting anticipated--not 
proven--flight rates. As we have previously reported, both SpaceX and 
Orbital are working under aggressive schedules and have experienced 
delays in completing demonstrations.[Footnote 12] SpaceX flew its 
first demonstration mission in December 2010, some 18 months late, 
because of such factors as design issues and software development. 
Currently, SpaceX's next demonstration launch to the ISS has been 
delayed from November 2011 to late April 2012 because of additional 
testing and resolution of some technical issues such as 
electromagnetic interference. Likewise, Orbital experienced 
programmatic changes and developmental difficulties that led to 
multiple delays of several months' duration. In May 2011 testimony, 
[Footnote 13] we noted that Orbital's inaugural demonstration mission 
had been delayed to December 2011. Currently, this flight has been 
delayed further to August or September 2012, primarily because of 
issues related to construction and testing of the launch pad at 
Wallops Island, Virginia. NASA has made efforts to accommodate delays 
in commercial vehicle development, including use of the final shuttle 
flight in July 2011 to pre-position additional ISS spares. However, if 
the commercial vehicle launches do not occur as planned in 2012, the 
ISS could lose some ability to function and sustain research efforts 
due to a lack of alternative launch vehicles to support the ISS and 
return scientific experiments back to earth. 

If the international partner agreements and commercial service 
provider contracts do not materialize as NASA plans for the years 
beyond 2016, this could lead to a potential cargo shortfall. As we 
reported in 2011,[Footnote 14] NASA's strategic planning manifests 
showed that, when anticipated growth in national laboratory demands 
and margin for unforeseen maintenance needs are accounted for, the 56 
flights NASA was planning for at the time of our review might not 
cover all of NASA's anticipated needs. These shortfalls amounted to a 
total of 2.3 metric tons--approximately the cargo that one SpaceX 
commercial vehicle will be able to transport to the ISS. As of March 
2012, NASA has cut its planned number of flights from 2012 through 
2020 from the 56 flights we reported to 51 flights. However, its 
current ongoing analysis is no longer projecting a cargo shortfall 
even with the decreased number of flights. According to an ISS program 
official, cargo estimates, particularly beyond 2013, are for planning 
purposes and could change as they are updated frequently based on 
launch vehicle availability and the ISS's need for spares. 

NASA Lacks a Domestic Ability to Transport Crew to the ISS until at 
Least 2017: 

NASA faces two major challenges in transporting crew to the ISS--
adjusting its acquisition strategy for crew vehicles to match 
available funding and deciding if and when to purchase crew seats on 
the Russian Soyuz in case domestic commercial crew vehicles are not 
available as planned in 2017. In 2010, President Obama directed NASA 
to transition the role of transporting humans to low-Earth orbit to 
commercial space companies. Consequently, in 2010 and 2011 NASA 
entered into funded and unfunded Space Act agreements[Footnote 15] 
with several companies to develop and test key technologies and 
subsystems to further commercial development of crew transportation 
services. NASA's intent was to encourage private sector innovation and 
to procure safe, reliable transportation services to the space station 
at a reasonable price. Under this acquisition approach, NASA plans to 
procure seats for crew transportation to the ISS from the private 
sector through at least 2020. 

In 2011, we reviewed NASA's plans for contracting for additional 
commercial crew development efforts and found that the agency's 
approach employed several good acquisition practices including 
competitive contracting that--if implemented effectively--limit the 
government's risk. As we also noted in that report, NASA's funding 
level for fiscal year 2012 is almost 50 percent less than it 
anticipated when it developed its approach for procuring commercial 
crew services. Given this funding level, NASA indicated it could not 
award contracts to multiple providers, which weakened prospects for 
competition in subsequent phases of the program.[Footnote 16] The main 
premise of its procurement approach to control costs--full and open 
competition for future phases of the program--therefore was likely no 
longer viable. Without competition, NASA could become dependent on one 
contractor for developing and providing launch services to the space 
station. Reliance on a sole source for any product or service 
increases the risk that the government will pay more than expected, 
since no competitors exist to help control market prices. As a result 
of this funding decrease, NASA adjusted its acquisition strategy. The 
agency now plans to enter into another round of Space Act agreements 
to further the development of commercial crew vehicles and has delayed 
the projected purchase of commercial crew transportation until 2017. 

Additionally, the agency faces another looming challenge--a decision 
about if and when to purchase crew space on the Russian Soyuz vehicle. 
NASA will likely need to decide by the end of 2013 whether to purchase 
additional seats that might be needed beyond 2016 because the lead 
time for acquiring additional seats on the Soyuz is 3 years. However, 
in the 2013 time frame, NASA cannot be fully confident that domestic 
crew efforts will succeed because the vehicles will not yet have 
entered the test and integration phase of development. Furthermore, 
the decision to purchase crew seats on the Russian Soyuz is 
complicated by restrictions found in the Iran, North Korea, and Syria 
Nonproliferation Act.[Footnote 17] These restrictions prohibit NASA 
from making certain payments to Russia in connection with the ISS 
unless the President makes a determination. NASA currently has a 
statutory exemption from this restriction that allows certain types of 
payments, but that exemption expires in 2016. According to NASA 
officials, the agency has begun working toward resolution of this 
problem, but the issue is not yet resolved. 

NASA Faces Challenges Maximizing ISS Research Utilization: 

NASA's greatest challenge to utilizing the ISS for its intended 
purpose--scientific research--is inextricably linked with the agency's 
ability to carry scientific experiments and payloads to and from the 
ISS. International partner vehicles have much less cargo capacity than 
the space shuttle did to carry supplies to the ISS and no ability to 
return research payloads back to earth. The Russian Soyuz vehicle has 
some ability to transport research payloads back to earth, but the 
capability is minimal at only 132 pounds. As mentioned previously, 
SpaceX, however, will provide NASA with the capability to transport 
research payloads back to earth. Consequently, if the new commercial 
launch vehicles are not available as planned, the impact on ISS 
utilization could be dramatic. In the past, NASA officials have told 
us that the impact of failures or significant delays in developing the 
commercial cargo capability would be similar to the post-Columbia 
shuttle disaster scenario,[Footnote 18] where NASA operated the ISS in 
a "survival mode" and moved to a two-person crew, paused assembly 
activities, and operated the ISS at a lower altitude to relieve 
propellant burden. NASA officials stated that if the commercial cargo 
vehicles are delayed, they would pursue a course of "graceful 
degradation" of the ISS until conditions improve. In such conditions, 
the ISS would only conduct minimal science experiments. 

Nonetheless, NASA expects scientific utilization to increase since 
construction of the ISS is complete. The ISS has been continuously 
staffed since 2000 and now has a six-member crew. The primary 
objective for the ISS through 2011 was construction, so research 
utilization was not the priority. Some research was conducted as time 
and resources permitted while the crew on board performed assembly 
tasks. NASA projects that it will utilize approximately 50 percent of 
the U.S. ISS research facilities for its own research. As we reported 
in 2009, however, NASA's scientific utilization of the ISS is 
constrained by limited crew time. Limiting factors include the size of 
the crew on board the station; the necessary division of crew work 
among many activities that include maintenance, operations, and 
research; and the need to share research facilities with international 
partners. 

Per statutory direction, NASA has opened the remaining facilities to 
other federal government entities and private industry and is 
operating the ISS as a national laboratory. As we reported in 2009, 
NASA may face challenges in the management and operation of ISS 
National Laboratory research.[Footnote 19] There is currently no 
direct analogue to the ISS National Laboratory, and though NASA 
currently manages research programs at the Jet Propulsion Laboratory 
and its other centers that it believes possess similar characteristics 
to other national laboratories, NASA has limited experience managing 
the type of diverse scientific research and technology demonstration 
portfolio that the ISS could eventually represent. 

To manage ISS National Laboratory research, as we recommended in 2009, 
[Footnote 20] NASA selected a body in 2011 to centrally oversee ISS 
research decision-making. This body, the Center for the Advancement of 
Science in Space (CASIS), is charged with developing and managing a 
varied research and development portfolio based on U.S. national needs 
for basic and applied research; establishing a marketplace to 
facilitate matching research pathways with qualified funding sources; 
and stimulating interest in using the national lab for research and 
technology demonstrations and as a platform for science, technology, 
engineering, and mathematics education. CASIS has begun outreach 
efforts and has issued a Request for Information due back in March 
2012 that seeks to identify and gather information from entities 
capable of serving as implementation partners. CASIS plans to develop 
an internal database from the information collected via this Request 
for Information, which will enable identification of entities that can 
support payload development needs according to their requisite areas 
of expertise. CASIS will refer to this database when issuing 
solicitations for funded opportunities to support research payload 
activities. Since the establishment of CASIS as the management body of 
ISS research is relatively recent, we have not examined its 
effectiveness; therefore, it is too early for us to say whether it 
will be successful in ensuring full scientific utilization of the 
station as a national laboratory. 

NASA Has a Reasonable Approach to Meeting the Challenge of Estimating 
ISS Spares and Assessing Structural Health and Safety: 

We recently reported[Footnote 21] that NASA has an appropriate and 
reasonable approach in place to determine the spares needed for the 
ISS as well as to assess ISS structural health and safety. Estimating 
ISS spares and gauging the structural health and safety of the ISS are 
not simple challenges. Among the many factors to be assessed are the 
reliability of key components, NASA's ability to deliver spares to the 
ISS, the projected life of structures that cannot be replaced, and in-
depth analysis of those components and systems that affect safety. 
While some empirical data exist, because the ISS is a unique facility 
in space, assessing its extended life necessarily requires the use of 
sophisticated analytical techniques and judgments. 

NASA's approach to determining necessary spare parts for the ISS 
relies on a statistical process. The statistical process and 
methodology being used to determine the expected lifetimes of 
replacement units is a sound and commonly accepted approach within the 
risk assessment community that considers both manufacturers' 
predictions and the systems' actual performance. NASA also has a 
reasonable process for establishing performance goals for various 
functions necessary for utilization and determining through modeling 
whether available spares are sufficient to meet goals through 2020, 
but the rationale for establishing performance goals has not been 
systematically documented. 

NASA is also using reasonable analytical tools to assess structural 
health and determine whether ISS hardware can operate safely through 
2020. NASA currently anticipates that--with some mitigation--the ISS 
will remain structurally sound for continued operations through 2020. 
NASA also is using reasonable methodologies to identify replacement 
units and other hardware that could cause serious damage to the ISS if 
they were to fail. Through 2015, NASA plans to develop methods to 
mitigate issues identified and expects to begin implementing 
corrective actions as plans are put in place. 

Concluding Observations: 

In summary, although NASA has done a credible job of ensuring that the 
ISS can last for years to come, the question that remains is whether 
NASA will be able to service the station and productively use it for 
science. Routine launch support is essential to both, but the road 
ahead depends on successfully overcoming several complex challenges, 
such as technical success, funding, international agreements, and 
management and oversight of the national laboratory. Finally, if any 
of these challenges cannot be overcome, it will be contingent upon 
NASA to ensure that all alternatives are explored--in a timely manner--
to make full use of the nation's significant investment in ISS. 

Chairman Hall, Ranking Member Johnson, and Members of the Committee, 
this concludes my prepared statement. I would be pleased to respond to 
any questions that you may have at this time. 

[End of section] 

Appendix I: GAO Contacts and Staff Acknowledgments: 

GAO Contacts: 

For questions about this statement, please contact me at (202) 512-
4841 or chaplainc@gao.gov. Contact points for our Offices of 
Congressional Relations and Public Affairs may be found on the last 
page of this testimony. 

Staff Acknowledgments: 

Individuals making key contributions to this statement include Shelby 
S. Oakley, Assistant Director; John Warren, Tana Davis, and Alyssa 
Weir. 

[End of section] 

Footnotes: 

[1] GAO, NASA: More Knowledge Needed to Determine Best Alternatives to 
Provide Space Station Logistics Support, [hyperlink, 
http://www.gao.gov/products/GAO-05-488] (Washington, D.C.: May 18, 
2005). 

[2] GAO, NASA: Long-Term Commitment to and Investment in Space 
Exploration Program Requires More Knowledge, [hyperlink, 
http://www.gao.gov/products/GAO-06-817R] (Washington D.C.: July 17, 
2006). 

[3] GAO, NASA: Challenges in Completing and Sustaining the 
International Space Station, [hyperlink, 
http://www.gao.gov/products/GAO-08-581T] (Washington, D.C.: Apr. 24, 
2008) and NASA: Commercial Partners Are Making Progress, but Face 
Aggressive Schedules to Demonstrate Critical Space Station Cargo 
Transport Capabilities, [hyperlink, 
http://www.gao.gov/products/GAO-09-618] (Washington, D.C.: June 16, 
2009). 

[4] GAO, International Space Station: Significant Challenges May Limit 
Onboard Research, [hyperlink, http://www.gao.gov/products/GAO-10-9], 
(Washington D.C.: Nov. 25, 2009). 

[5] GAO, Commercial Launch Vehicles: NASA Taking Measures to Manage 
Delays and Risks, [hyperlink, http://www.gao.gov/products/GAO-11-
692T], (Washington, D.C.: May 26, 2011); International Space Station: 
Approaches for Ensuring Utilization through 2020 Are Reasonable but 
Should Be Revisited as NASA Gains More Knowledge of On-Orbit 
Performance, [hyperlink, http://www.gao.gov/products/GAO-12-162], 
(Washington, D.C.: Dec. 15, 2011); and National Aeronautics and Space 
Administration: Acquisition Approach for Commercial Crew 
Transportation Includes Good Practices, but Faces Significant 
Challenges, [hyperlink, http://www.gao.gov/products/GAO-12-282], 
(Washington, D.C.: Dec. 15, 2011). 

[6] [hyperlink, http://www.gao.gov/products/GAO-05-488]; 
[hyperlink, http://www.gao.gov/products/GAO-06-817R]; 
[hyperlink, http://www.gao.gov/products/GAO-08-581T]; 
[hyperlink, http://www.gao.gov/products/GAO-09-618]; 
[hyperlink, http://www.gao.gov/products/GAO-10-9]; 
[hyperlink, http://www.gao.gov/products/GAO-11-692T], 
[hyperlink, http://www.gao.gov/products/GAO-12-162]; and 
[hyperlink, http://www.gao.gov/products/GAO-12-282]. 

[7] National Aeronautics and Space Administration Authorization Act of 
2010, Pub. L. No. 111-267 § 503. 

[8] In 2004, President George W. Bush established a new space 
exploration policy--A Renewed Spirit of Discovery: The President's 
Vision for U.S. Space Exploration (Vision)--which called for the 
retirement of the space shuttle and development of a new family of 
exploration systems to facilitate a return of humans to the moon and 
eventual human spaceflight to Mars. 

[9] In 2008 and 2009, the ATV and HTV vehicles respectively flew to 
the ISS and docked at the station to demonstrate their capabilities. 
In 2011, both vehicles again launched. These flights were the second 
for both systems. 

[10] The Antares was previously known as the Taurus II. 

[11] NASA has awarded contacts to SpaceX and Orbital for cargo 
resupply services to the ISS through 2016. Planned follow-on 
commercial resupply vehicles are the vehicles NASA will use for 
flights beyond those currently under contract. 

[12] [hyperlink, http://www.gao.gov/products/GAO-09-618]. 

[13] [hyperlink, http://www.gao.gov/products/GAO-11-692T]. 

[14] [hyperlink, http://www.gao.gov/products/GAO-12-262]. 

[15] Space Act agreements are transactions other than contracts, 
leases, and cooperative agreements. Congress granted NASA the 
authority to enter into these types of transactions in the National 
Aeronautics and Space Act of 1958 to give the agency greater 
flexibility in achieving its mission. Pub. L. No. 85-568, § 203(b)(5). 
Under a funded Space Act agreement, appropriated funds are transferred 
to a domestic partner, such as a private company or a university, to 
accomplish an agency mission. These agreements differ from Federal 
Acquisition Regulation (FAR) contracts in that they do not include 
requirements that generally apply to government contracts entered into 
under the authority of the FAR. Unfunded agreements accomplish the 
same goals but no appropriated funds are transferred. Under such 
agreements, the company can benefit from NASA's experience, guidance, 
and advice and NASA can gain insight into the company's system. For 
more information see GAO, Key Controls NASA Employs to Guide Use and 
Management of Funded Space Act Agreements Are Generally Sufficient, 
but Some Could Be Strengthened and Clarified, GAO-12-230R (Washington, 
D.C.: Nov. 17, 2011). 

[16] We reported in GAO-12-282 that, although private investment was 
anticipated from the commercial companies, without government 
investment, the commercial market for launch vehicles alone may not 
continue to grow and provide more than one contractor that would be 
able to compete for subsequent phases. 

[17] Pub. L. No. 106-178 (2000) (as amended), codified at 50 U.S.C. 
§1701 (note). 

[18] This refers to the 2003 loss of the Space Shuttle Columbia, which 
resulted in NASA suspending shuttle flights until 2005 while 
investigations were under way. 

[19] [hyperlink, http://www.gao.gov/products/GAO-10-9]. 

[20] [hyperlink, http://www.gao.gov/products/GAO-10-9]. 

[21] [hyperlink, http://www.gao.gov/products/GAO-12-162]. 

[End of section] 

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