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Government policy, innovation and economic growth
271
Government policy, innovation economic growth Lessons from a study of satellite communications
and
*
Morris TEU BAL
Edward STEINMUELLER Sumford lJnr~>ersiy, Stanford, CA 934W. Final
version
received
February
ll. .“.A
1981
The pnprr analyzes NASA’s imoivement in the de\-felopment of satellite communications technology. It begins by a historical acc( unt of the mairl developments which culminated into first commercialization of the technology in 1965. The description
highlights
It also provides
NASA’s
role iil accelerating
important
background
ing the COSIS of NASA’s
involvement
this process.
information and some
for measuraspects
of the
benerits. namely part of the ‘direcl’ benefits achieved in the initial applicalions segment (transatlantic voice communications). The paper then analyzes a number for the success of NASA’s involvement. the efficiency
of factors responsible both with respxt to
‘baseline’ technology
of the
arrived
at and with
respect to the transition from early R & D to commercialization. A comparison is also made with othrr less successful cases of governmeni
mtervention
to promote
new technologies.
’ Funds for the support of this study have been the NASA-AMES Research Center, Mofff:tt fornia, under Interchange No. NCA2-OR7455815. We are especially and
grateful
help in defining
Federal taking
R ,Sr D and satellite
to Harry
communications
has also given generously advice grateful.
and Our
to Harold
a project
encouragement. thanks
Hornby
allocated 5:, Field, Califor his advice
on the economic
impact
Goett
suggested
for
having
as a case study.
Harry
of hi,; ime and provided
of
Goett
important
Finr all tr’lis we are extremely
to P. Bar:;ellini,
L. Jaffe.
A. Jones
and
Professor Lusil,:nan for their cooperation a+ various stages of our work and to J. White. H. Halley. G. Allen Smith. D. Smith, J. Har., and Dr. R.T. Jones who projfided useful background inf xmation on the activities and Impacts of the National Aeroniautics and Space Administration. We appreciate the comments gested improvements
of two anonymous in an earlier draft.
Research Policy 1t (1982) North-Holland Publishing
referees
who
sug-
271-287 Compaq
0048-7333/&2/(iOOO-0000/$02.75
,0 1982 North-Holland
1. lntroductioa The path leading to the maturity of industrial sectors is generally associated with a deceleration in their rates of growth. This has been pointed out almost 50 years ago by Simon Kuzmts. An important implication of this trend is that any economy wishing to maintain its uggrt>glIfe growth rate should be able !o generate a continuous flow of new industries [ 11. Federal R Rr D may stimulate I,his process by inducing the private sector to undertake radical innovations which would other\viAe Ilot be undertaken or who:.e introduction lvould be seriously delayed. The red:lction in the technological and in the market risk of the innovations. consequent to Federal R & D programs. ma); counteract the forces responsible for deceleration. including the observed tendency of some established industries to follow an evolutionary rather than a revolutionary parth of technological drvel. opment. Our purpose; here is to illustrate .cnd give somt’ structure to the above in the context of and basec on the experience with satellite communication> In addition, we will attempt to measure somr’ aspects of the social benefits derived from this neu industry and to address the question of the chart of these benefits which may be attributable to NASA. The report is organized in three sections. Section 2 s a historical description of technola$ cal developm!:nts in communications satellites. It:. in tt:t emphasis is on f‘ie efforts whicl, culminated first comrr;erciaiization of the technology in !%5.
is made to &scribe the events in the c~~~tcr;t of our knolvledgc of innovation processes ,n genrral and 10 describe the activities and irnp;~ts of NASA. Section 3 addresses the issue of the benefits to society from NASA’s efforts in :,;ltcllitc communications. A dlstinc.ion is propo,ed heti\,ecn a ‘baseline’ communif:ation satellitc tcchq~logy and subsequent developments. An ;~rgumcnt is put to attribute ali th:: ec.)nomic hencfith of the former to NASA. A ~zc\mputalion of Finally, part of these bcncfits is al50 presented. Sectic,n 4 discusses some of the i:.surs which emerge
.At
from
~lctcfnpt
th,lr ca\e study.
2. A historical dc~elopment
and techuologicd
of communications
suney
of
the
satellites
The development of communication satellite technology and NASA’s involvement in the area can be broadly divided into three stage!;; invention, demonstration of feasibility. and commercial development. The invention stage includes a series of critical experiments which determined that no physical barriers to orbital transmission and reception of signals existed. In thr demonstration of feasibility stage a wide variety of system designs were tested with important knowledge and skillcreating implications for emerging supply companies such as Hughes and GTF1. Finally, with the development of the quasi-,,rivate communications companies COMSAT and INTELSAT, commercial users undertook the contracting of commercial satellite communications systems and a variety of ground StatioIi installations. a “reduction to pract:ct” of the new technology. NASA played an active role throughout its period of involvement. 1958 till :he early 1970s. in the development of the c~~mmuni~ation satellite technology by providing a research and development infrastructure and b? contracting for operating systems which steadil) increased in capabilrties and performance. NASA’s research and development decision making process invol+~ed a series of committees and solicited proposals which sought to define the major technological problems at each stage of the development 3rocess and to plan a series of design research .asks which would salve these problems. This ln‘rastructure also was a basis for determining the ialure Ol’ contract specifications when sp.;cific sysTerns were developed thus coordinating tc~chnologi-
cal policy with implementation. Communications satellites were vi:iualized in the 1950s as an alternative technology for coping with a basic constraint of terrestrial telecommunications, the curvature of the Earth. The Zarth’s curvature is a barrier because the propagation of electromagnetic radiation is linear. Before 1960 the available solutions were direct connection (undersea cables or a series of “links” on land) or high frequency radio transmission which utilizeui the reflectivity of the ionosphere to “bounce” signals over the horizon. The latter phenomenon of ionospheric reflectivity provided a basis for concenl about viability of satellite signal transmission hecause of the uncertainty of how efficiently signals could be sent through upper atmosphere layers. The SCORE launch demonstrated (ha! signals could indeed be transmitted and received with reasonable efficiency from an orbital position [2]. The next step in experimenting with the idea of satellite communications was the development of a passive reflector which would serve the same purpose as ionospheric reflection with more efficiency and reliability. The problems of cfficiencq aqd reliability had limited the growth oI intercontinental radio communications.
The ECHO program was based on this principle of a “passive” communications satellite. ECHO did provide ;I reliable means of “bouncing” signals over the horizon. However, ECHO by no means solved the problem of efficiency. ECHO proved thst the passive sate!lite approach led to a drastic limitation of power available to the receiving station because of the dispersion of transmitted and refll:c.ted siglnals. III the ECHO experiment OIIIJ one part ir: 10’” of the transmitted power (10 kW) wa> rlvailuble lo the receiving anttmna [2]. Oi COUTS~this limitation was known before ECHO’s launcn and ,the development of “active ’ satellite s4ystems was presumed to be the only really viable means of achieving substantial communicalions capability. The “active” communications satellite receives a signal and retransmits an amplified facsimile of the signal (usually with a frequent*? shift) [2]. The problems of active satellite dt+gn ar:‘ analogous t J designing teleconlii~ullic;Itic,ns links for terrestrial microwave systems uith the impor, ant added problems of the space envin:n-
mcnt.
weight constraints.
impossibilitv
power
Ilmitati~w~.
the fundamental
elements of NASA’s
demonstru-
(ion of a feasible satellite communications ogy and determined first
of NASA’s
mxj!;ior satellite programs,
could
satellite
NASA
was granted
authority
Defense
Department
design
not in
agrt;went
1961 to allot satellite
rese,rch
prohibited
1960
trolling
to \+orh
technological
[3]. Defrnce hrcauw
agreement abridged in
of
commune-
of the a.!iificult\ of ~cln-
acce~ to knowledge of >*Jch private]? demonstrated
n~logy.
by pioltecring
commercinl
by a great
occurred without
NASA
speculation
parties
to
\vould have
is of course counter-fact-
but
does
point
NASA/DOD
relations
may
to
InIlitary
dr\&pmcnt
exclusively
potential5
many
What
development.
Jc-
the tech-
the commercial
and this led tc>pressure
ual
in
terri-
interest.\ ma> hrtive
development
veloped hystemh. NASA.
allow
until
to engage in i:e’~~~nc’hroliou\
+.ate
cations satell~trs
on
proceed
had to be further
NASA
of the
U’orb
tory by reviwng in 1958 DOD/NASA [3]. This
technol-
the design problems
active
formerly
end
of maintenance. These pr~,hlemz uuc
have
out
hridgcd of
th;:t
;I barrio CC~IWI~LIII~-
cations satellites.
-.? .’ . RELA )’ The
RELA”.’
prt>gram .~uccrssfull~ pl,wwC’d
wrirs
of
na;tjoi
fil,\t
uses
of
innnvat1ons
Wave
Trclveling
a number
!+.‘Ctz.
of
da1 ;I transmitted,
improvements
including
[4]. The
fi3ts
ground
in
station
RELAY
other
the
0ptimiLation
subsystem
derstanding
as
of the radiation
space
environment
f,tud
Report
681 -6X7). Technical transmitter
(Picknrd
ON the
trchnrque data
communicnkn
well
and
enhancing
as
[4] pp.
1 I 1. 1 15 and
Rciclq~ 1 Froy~u~z characteristic5
SUJ dards (Pickard
[4] pp.
of the satellite \\ith cxistlnp
[4] pp. 116. I IS).
111sptte of serior .; problems kvith the pwtrr and
3
last
that
the TWT
container, mental this ;iswss
minute
the
discoveq
which
system
nrcessitatrd
as designed operate in a pressurized
RELAY
I did
The
goals.
progrnm
un-
(high energ? partii.lt’I
Lvert‘ chosen to conform
international
af
I misbion \{;I> de-
of
design
in
t>pch
sIgned to provide a great deal of sngintwing allwving
;I
r>f the
tube amplifiers
importan!
and
ant
should iiccL1rac~
by determining
IIUSI
accomplish of
dJt,r
he strzwd. of
il:.
cqwr1-
accumulated It \
rrhroadca~ting
the exact deviation\
b\
poaihlc
tk\
: .‘!I1 quit (‘1 rrrcri\ed
launch. Tht: basic problem of orbital placement W;IX solved in spite of thi4 failure: prclund :,tation tracking rrj.ealrd SYNCOM i had ci nearly idcal orhit. The failure of SYNCOM I to sc’r\‘c its
()j~e critical limitation of the ll~~~-~~ll~l~~~~ll~~~~ design of Io\ver pon’cr. such as RELAY I. \\:I, 11-1~neccssrtv for tracking (moveable) antennas. Thi> nccesssrily limited the number of facilitics rvhich could reliably receive ~:xttXded COIlln~unicatiom hecause of the high crtat of each staticjn. It also dictated a very high investment in 55atellitr systems if continuous comniun*cations were to ht2 an objecti\,e since it implied a siring of \atellitrs so that at least one sa,cllitc would always tbc ahove the relcvnnt receiving area. For these reasons, the po>sibility of a major re-de’ ign of the basic satellite-ground station system wa$ proposed by Dr. H. Rosen of Hughes [a]. Hughes was un:ible to sell this idea to the Department of Defen.,e or any corporation large cnouph to support the development costs beyond the exploratory stage accomplished at Hughes [9]. We may speculate that the major reason for the difficulty of selling the Hughes system was the risk of an entirely new system when a known. albeit expenGve. solution was knolvn to exist. It is also important that J. Pierce. of Bell Laboratorics expressed severe criticisms of the proposed geosynchronous :.atcJiite because its altitude would entail a delay in c ,nlrrrunications of 0.46 seconds which Pierce ‘>ellrved detrl.nental to “quality” of tclrcommunication service. However, NASA finally ~‘~1sable to support research in the area which led io the SYNC’OM I. In order to do this NASA had to obtain another agreement with DOD concerning gee-synchronous satellites. an area which had previously been the exclusive domain of DOD by agreement with NASA. Authorization was achieved in 1961 permitting NASA and Hughes to joint11 dcvclo;, the SYNCOM I satellite (see [3] p. 12). ‘fhe fundamental design problems of achieving :I 4vnchronous c>rhit and broadcc:s:ing a continuous higna1 to Earth were solved by Rosen and his rchearch group at Hughes. NASA awarded a controt to Hughes in Aqust 1961 leading to the February 1963 launch of SYNCOM I (see [3] p. 14). L’nfortunatelv a n trogen tank explosion destrovcd the con;munic;ltions capahilt\ during
x:lleIIite
communications purposes, in spite of an expenditure of $20 million to develop. m;:nbfacture, and laurch the satellite, would have been a severe blow to the development of an exclusively private satellite indu;tr!,. Because such risks were known b) NASA and direct payback was not an issue in the calculus of mission decision, NASA prepared and launched the backup satellite SYNCOM II in July of 1963 [3]. SYNCOM II was not designed to he a truly geostationary satellite hut rather to maintain an orbit which caused it to move a distanr,: of 33 degrees north and sot‘th of a,id perpendicular to the equator (see [3] p. 16). Midwest Research Institute has catalogued a long list of improvements incorporated in the SY NCOM I.1 program including technologies for transfer orbit, antenna array, automatic station keeping, and a variety of improvements in power and communications subsystems (see [3] p. 15 - 16). I .le major experimental purpose of SYNCOM II wa: to establish the feasibility of the semi-station.:ry orbit and provide engineering data on c:,mmunicatlons design SYNCOM II was so suecrssful in esrablishing the viability af synchronous satellites tha,: civilian communications satellite systems have subsequently uniformly heen of ‘he svnchronous design. Back in 1961. the viahilit.? of i synchrr;notus orhit solution was severely doubted. The ADVENT program, an Army synchronous satellite system. had been running into difficulties which eventually led to its demise. Thus. in the context of 1’36\, if SYNC’OM had not beer1 successful there is every reason to believe th&t the present predominant technology for communications satellit’e orbits. synchronous orbits. would have emerged at a much later date if at all [IO]. This success v$as the basis for taking mc:h of the risk out of d,:crloping commercial communication satellites. Tile SYNCOM Ii1 satellite. which achieved a near perfect geo stationary orbit in August of 1’464 was followed less than one year later byi INTELSAT I, the first commercial communications satellite [ 1 I]. The SYNCOM III achieved a truly geostationary orbit and demonstrated the technology \k:‘ automatic station keeping which WPS another link in the development of synchronous satellites. I’~u
:lapecth 0f thi5 station-keeping ?cwtant
further
1~
capability
dcwlopmcnts.
ground Iracking w25 inferior
in accuracy 1(.>in-orhit
btation keeping and the diwwq “ tri-axialiry,”
of the Iiarlh’h
pear shapcdnrss.
Lvhich rnrani
impulse power to preserve stationarity cantly less than originally cxpect::tions. mere
accurate than
position
the
u’as signifi-
anticipated.
on-board position
iuwxpected
wcre im-
the dihcc?\.cr\that
Contrlrrv
to
sensing \vas much
terrestrial
observarion.
accuracy of onhoard
sensing 2nd correction.
station
The
keeping.
set a standard
of
accuracy which would for several Fears focus technical eff,ort This
to improve
phrnnwa-wn
ground
aspect c>f technological terms
the 11llure of focusing inane;‘.
The
mtlchaniams
hy
potrntial
dards and specifications a pnrtiwlar
tracking.
change [ 121. In cconcmic
they provide a clear aandard quality
station
of focusing; is also an important
system
is that
which to mwsurc
user can use htan-
IO relate the cost of using
to its capabilities,
The
tatter
development ( the discovery of the pear-shapcdness of
Earth
(though
propriately
Ihe
analogy
is
more
ap-
an over ripe peach that has been picked
up firmly
in the horthern
hemisphere).
ample cf a rare but significant gineering.
the discovery
model. While
does not benefit
in en-
of a new physiclri
ple white engaged in solving well-defined
is an cx-
happening problems
princi-
txithin
much engineering
from a scientific
;1
\vorh
model (the phr-
nomena tire 100 complex to he completcl~
sprci-
fied or too new for thcorv to have caught up \\ith practice). l~rce
it is somewhat
modifk~tions
in
rare
for
enginwring
10
the models it does ust’. In
t.lis case the technology of geosynchoronous
satcl-
I~.es was a more attractive
option when thl: knowl-
edge about
state of
the physical
changed by empirical standards.
and specification
communications
the world
observation.
satellite
By
~~3s
1964.
of ;I particular
the
type of
were set and the major
questions
facing the commercial
the costs
they wwld
face in
drv&prrs
\\crc
implementing
the
technology rather than developing i::.. ‘The pattern of incremental earlier The
was apparent
development
W:;ve Tube
of incremental versus
2s
Traveling
9s well as changes aimed at
the specilic cntastrophc of SYNCOM
mad,e S),‘NCOM 111; solar
noted
program.
of a non-pressurized
amplifier
eliminating
improvrmer,t
in the SYNCOM
II an improved satellite. changes occurred nith
power in
collectors
SYNCOM
delivrrcd
II. bandwidth
I
A series
SYNCOM 32.5
~valls
went from
The contributions of the ATS program to techprogress in satellite communications arcs numel~ous and dislributed over a considerable number ol ~pecialily areas. Table ! itemizes sonic of these contributions. The specific intent of the .ATS program LV;IS tCJ explore IW.V technologies for application to later aatcllites. Among these techfor multiple ac_Y)rb. nologies 1ver~2 capabilities aircraft commLlnication. spin scan cameras (color ;md black and Lvhite). position \cnsing. operation in IIC’I\ frequency bands. and improvements in inl‘~;rm,itin;n codrng tichniqut’ (see 131 p. 23). ‘The I973 ATS-6 satellite ua5 an impctrtant hrcaktrhough 111achieving high orbital broadcast po\\cr and dralilutically reducing the size and cost of t:artt-;’ ha.4cs-I receivers [ 141. no!ogicnl
‘l‘iw most important observation ahout “iese I :chnical imprc>\~cments is that some of them “p;~ce” the developments in commercial satellite technology:. That is. NASA programs generalfiy led III the development of the major techn~~logical xdu:icvis ;o commercial hatrllite problems. III tahltl 2 wc have comparccl a series (?I” such major design solutions transfcr:cd from NXSA contract to commercial hatellite s\,stems (often constructed h\. the same contractorsi (see [3]. pp. 47--4X). The impc)rlance of NASA’s t~:chnolopical lr:~d is twofold. First. NASA had a :4gnificant id in cspericncc over the commercial sector and \%5’aspursuing
<)hjrctivrs 0: a more icchnological character (thus NASA was pl:rhaps less constrained by cost considrrations), Second, NASA appears to have adopted an expiicit policy of taking relatively large risks in order to extend technical capability whereas user firms such as COMSAT have been more cautious in their explorations of new technology. tending to make improvements within existing system design. The latter point is particularly relevant for current NAL;A policy.
3. NASA’s
contribution:
Cost-benefit
analysis
The history of satellite communicatir;ns technology (s.c.t.) a::id of NASA’s role suggests that it may be useful t,;, distinguish between two periods: the period prior to the first commercialization of s.c.t. in 1965 and the period after 1965 1151. We will argue that NASA’s contribution was decisice in the first period and therefore that the direct benefits from the s.c.t. of 1965 - henceforth termed the baseline satellite communications technology, h.s.c.t. - should be Jui!~ attributed to NASA. A preliminary calculation of these direct benefits, for the first sub-market telephony between the U.S. and Europe ,Nill follow. After 1965, the direct contribution of NASA seems to be rather small. rt&rtivc to its contribution in the previous period and probably tc the contribution of the companies directly participating in the commercial exploitation of S.C.I. N.ISA’s contribution is basically an indirect one - <)f having been responsible for the b.s.c.t.. upon wllich the dramatic improvements in s.c.t. occurred. ;l process which enabled rhe grad-
ual diffusion
of this technology
among
;in
increas-
ingly wide spectrum of applications. It ivill he argued that existing co5t benefit analIsis is. I-J\ it.si’lf, inadequate to evaluate these bencfit3. the reason being our lack of an adequate conceptual framework which will consider (I) the timing of introduction of new technologies by the private
sectnr. (2) the competitive reaction of existing technologies to the threat:; posed by new rechnologies: and (3) the external economies ,Nhich any application pro\ ides to those firms engaged in subsequent
applications.
Without NAC A’s involvemezi. ~hr introduction of the b.s.c.t. u .)u/d have been delayed. at Ieast br:,ond the date where its efficiency was surpahJscd by that of the alternative cable technology [ 161. The technological history of NASA’s involvement in s.c.t.. is proof of the criticality of this involvement for the emergence of the b.s.c.t. The opinion of experts prior to NASA’s involvement Land after failure of the AD\,‘ENT program was ovek,whelmingiy pessimistic about rhs prospects of a commerclaliy viable synchronous satellite communications system. The MRI study (carried out in 1470) si,ltes: “Only slightly more than 10 year!, ago. many experts had serious doubts that: satellites could survive in space. and operate long enough to paw out; th,e quality of satellite communications transmissions would bt: acceptable; and that the cc .t of satellite systems would be competitive wi’h traditional earth-based communication.”
131 This outlook was lar$,ely responsible for Dr. Harold Rosen’s inability to “sell” the idea of a synchronous satellite to either a military or a civilian ager-t; NASA’s taking over of the project was essential for the successful development of s.c.t.. at least during the 1960s [IO]. Some quantitative evidence on expenditures on R & D and engineering efforts also bears upon the previous conclusion. NASA’s expenditures on s.c.t. between 1960 and 1965 dwarf that of any other agency or firm potentially interested in a viable commercial system. Hughes’ accumulated expenditures prior to NASA’s taking over the synchronous satellite project amounted to approximately I million dollars [IO]. The accumulated expenditure of
SYNC’OM
ATS-I
ATS-I
SYNC‘OM
(Altilde
(Low encrg~
(Electronic
( Broadband
hcnwrs)
proton
phased array)
25 Milr)
ATS-I
damape)
ATS-III
(
(Spin ~a~,lhill-
(Mechanically
ATS-III
/ation)
&spun
(Dual
II
array)
III
ATS-I moclc)
(PVIWICI ccrn~rol; (Polang Irtrirude) SYNCOM
III
AI-S-i
SR&7 power
II
(Tri axdlity
(RF
and pr:ivity
hirndling)
(Shapd
pcltellllal)
(RFI
crwr3gc)
problem;
(I Ical
SK&T (High
SK&T arc’2
output
TWTs)
pipr
cooling) A?%F&G
(Low
ATS-F thruhr
Al%F&G power
arrays)
jets)
SK%‘1
(30 II deploy-
ATS-V
ahlc array)
(200 \\a11
(Slip rings)
SR&T (Flcxrhlc
(Hi@,
TWT
hod\
I2 GH,)
CffCClh)
(Multipactmg high power
PF
components) .AT:s-lll
SYNC‘OM
ATS-I-
ATS-I
III
ATS-III (On
hoard
processing) (40 watl L band)
tion ant! maintenance cos:ts, administration costs, ground station investment costs (fol the salellite c~nly). tails (for ;*ahk onI\,). and possibly profits 2nd taxes. Lashc j UIC~O~en’s figures for tht: cha ‘e of 5atrllite inve tment costs over tota: cost; for Intellsut were 4 percent and 43 percent for the TAT-5 and TA.1 ‘-6, respectively [2U]. There ‘ore. use of satellite investment costs and cable in\ ‘tment costs in ou,’ calculation is ~_~~~bably ind,cative of the relatio iship between total satellite costs and total cable costs [Zl].
(2) Period:
The
relevant
period
ends
witk the
mlnimum of two dates - the expected data of introduction of the b.s.c.t.. under the assumption of no NASA involvement, and the actual daie when Cable Technology in use became more efficient than the b.s.c.t. Table 3 qhows the relative efficiencies of the various TAT cables. The design life of these cirbles is 20 year!. The efficiency of the INTELSAT I technology is given by the figures below [22!: --~_ Investment, $9 000.000 InvestrrLt cost per Design life. 1.5 years capacity circuit, Circuit capacity. 240 per Fetrr, $25.000 _ _ _ _ _ _ _ _ _ ._ _ _ _ _ _ _ _ _, _ _ _ _ _
.~_.__ SpJcc
-__.__ lxth
wgmcnt
wgnwnt
--. Channel
Down-link
ground-station
C’p-!ink
~~rcwnd-~tatt~~n
capacity
frequerq
tranzmlt
frrquenck
rt’ca\c
antenna
SYIWOM
II & 111
AT!+I (Buvlding
SYNCUM
II & III
feed .)
ATS-I
A-E-V block)
(C‘a5wgrdrn
dntrnnd
(Millimeter
waves)
ATS-III
( PWIJC~mon~~pulwt
(C‘hannrliration)
SRJrT
AX-F
ATS-V
SK&T
II (SHF and
ATS-I’
ATS-I mcler
(Sm311 and
mrlli-
tranqxwtahle)
*ilrt
propagati’on)
ATS- I
SYNC-Oh1
AT%.-III
AT-S-III
AT!;- F
ATS-F
(\‘HFI
(L’HFI (L-hand)
SYNC’OXZ III ATS-I (AKINC’I A N-III (OfIt!,
To find the present value of the investment cost per satellite capacity circuit for a 20-year period the cost figure which has to be compared with unit circuit cable costs of the last column of table 3 we take the PV of $25.000 per yca~ for a period of 20 years discounted at 10 perlzent interest rate, PVS: PVS = 25,000
1 - U/l.lP’ 0.1 i
I,
_ 213 ooo * .
.\‘I S-i’
_____Ysdr
Lengtlh (nautical
Inilial Invest-
de\)
mcnt
In~edn-13~8
C’ircuir Upacllr
cm1 p:r ;lllcrn.ll; circuil
__ 1956 I Y5Y lY63 lYh5 I’)70 I’)76
2.2hX 2.531
44.9 42.0
3.514 3.509
46.4
3.600
I9 I .o 2YO.O
”
(4) Unit resource savings: Point (ii) above implies [26] that 0ur calculations implicity ,sre made on the assumption that cables are perfectly divisible in capacity while indivisible in lifetime. This is unrealistic but enables us to avoid the problem of having to decide the titning of introducti’on of the
Tahlc4 SaLc!iite circuits .-- U.S. ~Europe --- ~--_-----_-
,!elcphony
”
- _-
! 965 1970. WC dcL+drd to calculate reWurce sav~ngb over the volume of satellite trafiic in ZISC r,ither than over satellite circuit cq~~ir~~. The former would bc closer to the amount that TAT-4 cables would have I.O substitute had the h.s.c.t. not been available. The calculation based on satellite circuit capacity is also made for reference purpo~1~‘s.Some additional assumptions are implied when using this measure: (i) Satellite circuits in ~-se during the period wou!d not be substantially low ‘r had no improvements beyond the b.s.c.t. occured; (ii) the additional cable circuits of the TAT-4 type that would be installed in the absence of the b.x.c.t. are roughly equal to the satellite circuits actually used during the period [25].
XX0 X75
4X 4X
46.0 X7.0
3.44 I 3.692
IYX5 h
--
____
__.
_-_
141 i3X
329
X45 4.r)w
IO3 4x
I ?.rNO
333
?.4 h
h
-
--
addition;:; TAT-4 tcchnoi~~gy cables which would have been laid had Ihe b.s.c.t. not become available. In any case, it is doubtful whether our calculations would have bel:n significantly altered had that decision-making been explicitly taken into account. Under our assumptions, 20-year circuit resource savings, discounted, equals the difference between: (a) unit circuits costs with TAT-4 technology. which are paid at the time the additional cable would be instai!ed. and (b) PVs = 213.000. This amounts to $120.1’;00.
The Culdution: The above elements of analysis enable us to compute the direct impact of NASA’s involvement in satellite communications technology in its first commercial application: telephony along the U.S. -Europe route. Table 5 indicates the procedure followed. Note that the resources saved in any particular year depend on the additional satellite circuits used or installed during that year, and not on the absolute number 0.’ circuits [27]. The present value of the resources saved is
uh-market ---
I965
1966
1967
64 64
72 8
165 x7
242 71
464 222
240 240
240 0
240 0
I.500 1,260
1.500
---
-~___
lY6X
~~-.--
1969
I970
0
5cxl Yb 6.000 3.470
$49.5 million when the calculation is based ~jn satellite circuits in use during the period. and $421.23 million when it is based on capacity. $49.5 million is, in our opinion, a lower bound to the resources saved from the first application of the b.s.c.t. There are a number of factors which would raise the figure: (a) the assumption that cable technology iv;ts independent of satellite technology. Experience tells US that slevelopments in cable technology were consider:.Sly accelerated by the introduction of satellite techlaology. This would tend to lengthen tbc period were the benefits from the b.s.c.t. should bt computed. ‘b) the unit circuit savings from the availabi!ity cf the b.s.c.t. are higher than computed due to the Lower design life of satellites relative to cables. Thus, after 1.5 years of life. a b.s.c.t. circuit could be substituted for a more efficient satellite technology, and so on throughout the 20 years of cl;ble life. Part of these. additional savings should be attributed to the b.s.c.t. because they would have occurred even without additional R & D and engineering resources explicitly allocated to improve the b.s.c.t., i.e.. through oper;tting experience. learning by doing in the producti,?n of hardware. and unpriced externalities received irom other sectors 1281. In our opinion, both of these I’acturs certainly outweigh by far an:, possible over-estimate in the
\,olume c>f satellite circu>th il: use \\ hich \\~~ld have been substituted b!. l.ablch in the ;th.\cncc of the
b.s.c.t.
The direct benefits front introducing thrs IJ.LC.I. the IL.!% f:uropc teleinto its first application I;hrmy sub-market. reprryl:nt , n import;mt share of :.tll the NASA expenditures itXading IO thih frchnolt qy. This share is :\t lea\t ;I third. and prohabl> much more. This is a rctnarkut~le achievement for the foilowing reasons: ( I() Satellite communications technology is a m;L_,or technoloq or innovation [29] ‘\I post-World War II indtl- :rial society. Yt is sufficient to look at the set of .wttiaE and potential applications of this technology in order to realize this fact (30). (2) The full impact of thih (like any) rnajcjr technology on econorn! (and sctciety) will makt itself felt only after ;I re;l>ol ahlb long period of time !3 I]. The direct impact anal> XJ previously refers orply to one sub-market tort?spending to one ;ipplication. i.e.. part of interniltional telephone trunklng. the first application &own in table 6. We doubt that we mav find caxe\ where the first direct impact of the huselinte tec!lnological level of a major innovation Lovered one third or one half of the co,:,ts lvithin h year>. NASA’s over-all contribution ni;b\ 1~ di\ &tf into three parts:
Data coll~~c.tion and relay High quality.
high
speed fnc:imilr One-wq
Satellite-lo,3atellile rcLi\
de@ tal
data distribution; financial Time
sharing
service.r
Meetin@ and polling Information
networks
Law and justice MedIcal and scientific:
(1) The resource savings due to the b.s.c.t..
in the first sub-market and in subsequent sub-markets or applications penetrated by it. The share of ~~111 resource savings due to (21 post-b.s.c.t. whicll >ilould i)e attributal-it to NASA. (3) The share of the value to society derived from the satisfaction of previously unmet needs. The first part is calculable and quantitative. it probably does not go very much beyond the international telephony sub-market because improvements beyond the baseline technology were essential for most of the subsequent diffusions of s.c.t. Cost-benefit analysis can be appropriately used here. The second and third components are ex,. tremziy difficult to calculate for the following reasons: (a) The technology beyond the b.s.c.t. is dut: to the joint action of the following factors 01’
agents: NASA as the agent responsible for the introduction of the b.s.c.t. upon which subsequent impr0vemen.s are based [32]. NASA as a contributory agent to post-b.s.c.t. [33]. commercial firms. INTELSAT and COMSAT, as contributors to post-b.s.c.t. (b) The diffusion of p3st-b.s.c.t. within and across sub-markets and applications depends 031 technology adoption and switching decisions of prikate firms. These decisions ai:e influenced by the pattern of unpriced benefits (externalities) generated in the various applications, especially the initial ones. Moreover, the third component requires some radically new roois or analysis. presumably a theory of needs [34]. Our empirical and theoretical knowledge of these processes is slight. This kaobvledge is essential for evaluating the impact of n?trjor innovations and the possible share which may be a.ttributabie
4. ksues emerging
from
kASA’s
imolvement
in
C.S. technology
Another aspect of NASA’\ acti\lt) concrlrn* the accumulation of J bnt9s ledge hd\e for cnginccrtng de\@. Tbi\ is an cffectl\c \\+I\ of stimuIat.ng I!X coml~lelcialszatinn of 3 techncllogv xincc 11 rn.i\
con:riderahl> rt!dJce the wart c>f finding AI (~~ptiSUCCC~~in the transition from earl, R Sr II (and baielinc technol ‘gy development) to cor,rmrrcialization can be iIscribed to LL numher of factor>. First. a suhsta~ tial portion of the R Br D and pr~~totypr development and building was prr-
formed by subcontractors such as Hughes which subsequently supplied the first (and subsequent) user(s) [36J. To a significant extent there was no need for explicitly transferring the design and manufacturing oapabilitics from Government to c#Jmmericai use. Second, experimentation by NASA of a variety of different satellite systems prior to commercialization led to a cost effective first commercialization of this major new tcchnoiJ’gY. !n this respect it is highly significant that NASA attemptetl C.S. programs of its own, over and beyond the jupport it provided to the proc,ram% undertaken by industry. The additional F: & 0 widened Lonsidcrably the range of technols\$es available for commercialization. and considerabr: reduced costs. Without NASA’s support, fil-st sommercialization would probably have rmbodied AT & T’s [37] low altitude system invoiving large numbers of satellites. instead of the edormously cheaper synchronous satrliite alternative invoi.Jing only up to three satellites. Third, the fact tilzt NASA sponsored ~@cutions R 8 D after having arrived at the basic design solution to S.C. synchronous satellites. This is important for two reasons: first, there are indivisibiiities in this research, since it is most economical. to ur,dertake a very wide spectrum of applications eu:oeriments together in the context of a givec program than it is to perform a series of indivi.iual experiments ezch one suited to the needs of a particular customer; second, there are spin-offs (externalities) flowing from research primarily useful for some applications \A:hich benefit other applica-
mum pornr deal?n frlr a particular applic;ttictn. Thus. the accumulated data hail rc*prtt\znt\ .I hnowledge infrahtructurr riemcnt I($ tnr InJu\tr\. which should he diffferrntiatcd from t,mplhlc capital infrastruc,turr components. In S.C. ;I 4uhataratial accum~td;lti~~n 0i knot\ ledge ;icc~mp.~nicd the RELAY and SYNCOM Programs. The? enhanced the understanding of the (high energ!, part~clc) sp:ice environment and enabled the optimlzsiian of c’omrnuni~:atic~n and other suh~~~t~ws.
Prior to prool’ of fc..lhihilit> of a basic dwpn s’olution. expected pri\ate hencflts ma\ he lsw .knd risks high so expected private utiliti of R & I) ma>’ easily be negative. Expcctcd wc1a1 utilit!. ho\vever, may be po5itil.c due to rxtcrnalitic> and 1owl:r social risk: relative to pritate rihh% ;\fter ;I basic design solution is arri\.cd at. the pr!\.itt* profitability (colnmercial rihh) of ~ub~qur:nt R 8: D whose objective is IO optimiLc. ad;lpt aud improve such a design incc*eascs (drcr~a~~\) [3’J]. Under these cctnditions. ‘baseline tetchnolog~ * R 81:D should be: sp,.msorrd by the (~jovrrnnlcnt x.vhiKe subsequent R & D should be left to the private sector. The above reasoning tvould hat-e ied N.&S.-\ t1.l launch RELAI’ and once its fsasibiiit> \~a> Fr~~~~d tc improve upon it in conjunction u.ith the pri\.itc sector. But \vhy did NASA undertake the Sj’SCO&I Program which led to a more effecti\e basic design solution? -The anhwer lies in the gap cr~\at~d ht:twdzn the social and private expected uuht> once the synchronous satellite idea became available. Given that there already existed a psn~~ed basic design (RELAY-type active satellite s>>tcmx) and tha: the nen proposed design V.X \er\ rihh> for private firms, the latter would not ha\.~‘und~r-
ta\,cn the pr+~t. at least as early ;lj NASA did. !,oci;il utility of the proH
have made sense. L’.T the development r)f a even before !hc full non-synchronous 5.c.
role of Government sponsorerl R & D mav have to bt: enhanced duri:.g depressictns rather than being reduced. Finally. foreign Governments. continued support of certain technologies may justify. in certain cases. enhanced (and possibly redirected) public support at home. We do not know of any rigorous criteria for identifying these cases in practice.
u,i.s full\ nzalized. Fcticr;tI supp.)rt for S.C. technology mdy be juhtifiecl e\i’n hr$ond the stage of first commercialir;itit>n. for ;I ..ariety of reasons. Firht. yrlvate firma may have :I tendency to risk. incrcmcntal R & D only and ptzrfc>rm lc)i\ ni;~. nr@:ct longer term research on technologie3. even when these offer a positive social utilit?. In thc:4e c~t~c~. governments should step in. The currctlt con:,er\atism of the satellite communications coinmercial sector and potential for significant (if rishy) advailce is observed by P.L. Bargellini of COMSAT in presenting a table of potential imprcwmmts based on new technologies. He commelits: “Table 3. xvhich summarizes the situation re\~!als at least four arcas in which the new technc11.~~ has not been tried. Since some of the:,e tcchnoiogies appear quite promising, it is a;>proprla:i: to hope that the im3asse between iile rrquilements of operational systems and the !‘c’ed for cxpcriment will be broken. The soonr’r ihis il~paase is over$:ome the better; hotvevt r. tht bUC’ 3.5 of “coli\,rntional” Latellite systems dnd spacecraft design appear~s to have been partidIly responsiljle for slowing down exrerime*- .I programs. This situation is not surprisin since it has occurred many times in the past 7’ other fields of technology where large investments in oper;&or?ai systems retarded the introq>uctior of ..jsystems and components based on new technologies. notwithstanding the potenti;il promise. [40]. Second. the gap bt tween private and soci;ll C.XJeL?c(i utility (including the risk and benefit ap?r( priability factors) of developing new technolog es nlay comeivably increase during depressions. The ca.%h-flow problems of firms may deter them more than in normal times lrom undertaking R S: D. On &he other hand, the lapid introduction and diffusicn of new technologies may be critical to overcome the d=pre*;sion. On both counts the
NASA’s support of S.C. R & D had a m,.l,jor cffcct on thh: structure of the industry. and this i4 bscause of the variety of role:; it played within the innovation process. If NASA had simply subsidized part of the ongoing R & D efforts of industry then it is likely that the domination of AT & T on both domestic and international t*ommunications would have continued. This is because AT B T was the only private company which h,uJ already undertaken a considerable R & Ti effort of its own and was capable to proceed through commercialization of its non-synchronous system. i’he fact that NASA - beyond supporting TELST&R - undertook programs of its own such as RELAY and more important]} the successful SYNCOM Program (based on the Hughes idea of synchronous sa!ellites) opened up both the communications and the satellite and communications rquipment markets. Thus. transatlantic telcphclne via satellite turned out to be owned and operated by an international consortium - INTE.LSAT and the U.S. part by a private,‘public ccrporation with a relatively broad-based ownersh,p (COMSAT). Similarly. the technological preconditions were created for rhc FCC’s 1972 decis,on assuring multiple-entry into the U.S. domestic. S.C. market. (Finally. NASA contracting created hardware and system expertise in a wide variety of firms such as Hughes. RCA. etc.) The first commercial application or ’ ML” of S.C. was the transmission of telephone and TV sig.ials across the Atlantic. In the early 1960s this was the only possible commercial application given the high cost of the existing medium and low altitude satellite systems, e.g., based on AT & T’s TELSTAK. The existing supplier of telephone services in this market was AT & T (via underwater cnjtes) alld the eventual supplier was INTELSAT. AT 8.z T h;:ld a 29 percrnt share of COMSAT. the compa:ly
representing
the U.S. in that consortium.
tion to the suppliers ttzchnology’).
In addi-
of S.C. services (‘users
we have the ‘final
sides of the Atlantic
represented
u:,ers’
of the
on
by 3 vxiety
both of
government
agencies. From all this it is clear -that the issue of NASA’s relationship with the ‘users’ is a complex one. Some ‘ user’-related aspects which were important for the success in the transfer or commercialization of the technology include (I) Support of the R & D programs of existing suppliers of services (i.e.. of AT & T’s TELSTAR Program) without neglecting experimentation with other technolc,lgirs. (2) Increa! ing cooperation ::ith European countries to coordinate experimentation. This started with
ICHO and continued with RELAY. 1961 the telecommunication agencies of the J.K. and France agreed to build the ground stations for these P-.qrriments. This pattern of NASA Ional cooperation with the ‘final sponsored into, users’ of the f rst commercial system, enormously accelerated and faciljtated the establishment of INTELSAT. Moreover. the chain of ground sta(ions built was one of the foundations of the global system (see Smith [37]) and presumably explains the speed of the technology transfer process . . In
5. Concluding I marks The paper is an attempt at evaluating the COIItri,>ution ot’ NASA to the emcrgaence af the S.C. indc.lstry. It coinbines aspects of the quaiitati\,r ilistory of the technology and a partial quantitative Analysis of the costs and benefits of NAS.4.s invoi\.emcnt. Prior studies, to our knowledge. have generally emphasized one or the other, so it n1a) be useful to consider the advantages of combining both. Two specific features of the work include: ( 1) A distinction between base-line technology development a;ld subsequent technological devrlopment. The distinction is important because the qualitative case histories show that the contribution of NAS 4 is clear and direct in the former and indirect in the 1a:ter. Therefore, a partial and relatively standared cost-benefit analysis of NASA’s involvement appears as a possibility. Our present too!s of analysis do not permit us. how-
technoiogy transfer issue sinrze firm:, like siemens which first commercialized did not t)a>e their technology 011 contr:.icts with the Government but on their own R & D efforts. Finally. the user of the new technology in the West German case was a relatively clearly defined entity .- utilities or combinations of utilities and its role in choosing the technology to be used was paramount. In tleither case is this the situation with respect to : .c. P-&ably due to very special in~ti;utinnal and tecklnological characteristics of the industry. NASA acd other U.S. agencies played a much more active role both in arriving at the optimal baseline technology and in determining the particular nature ,Jf the technology user who ;vould own and operate the first system on a commercial scale. These characteristics may a1so limit the applicability of NASA’s experience to (:ther instances of Government sul;port of large tligh-technology projects. significant
[I21
N.
Rosenberg,
Inducemrnt
I131
The
Direction
Mrch::nisms
Rosenberg
(ed.).
Universilv
Press. Camhridge.
the course
amined
h.rveral flight
other
on an identification of
advanrage
(6) (Novrmher.
rrcchani?m.
I x11thi:,
parlance.
The u-phase
and
phase
in
the
phase.
S. Kuznrtr.
(San Fransisco
/~uz.
und Profits
Prop.ss National
Science
That
is, heyond
of an industry.
K Iznrts’s cycle
initi:ll
and
Technr logical
in: P. Kel y
rent I(mde&r
i nd
to
ap-
NSF’s
Innovation
M.
A Crrfr d
Kranzbcrg
Kearew
q
Cur-
P,-ess. 19’15 j; J. Enos, ,Perro-
(MIT
Prt ,s. Cambridge.
Found,ltion.
Washington.
Mass.,
Inrerucrron
in the Innoootion
Science Foundation.
[I61
A Eli 1 I
hstwcen the n-phase
mno\.tiion
Growth.
Scrence und Techndogv
References
fEEE
8: .~.:wrn.~
proc-ss
also to S
TL’L.~~o/c>~I
1962);
might
and Performance.
to Enos’a distinction
correspond\
Economic
(eds.)
We
is to NASA’s
and so is the hrst course. of ac~lon. Description
and the /?-phase of the innovatibjn
‘innovative’
In
centered
1975).
This corresponds
phcation
ex-
auto-
program.
rnech.!nisrn
Trunxuc~rrons on A erospwc~ trnd Elearon
[ISI
authors
issurs ;.nd the needed
the planning
Redisch. ATS-6
N.
or resolve these issues was the
suggest. to u,e economic comparative
tie
irlcluding
the SETI
of technological
operative
W.M.
and
of a planning
IO clarify
in:
IOX- 125. study
programs
control
experimentation focus
1976)
NASA
surface
Change:
Ue\lces.
O,I Te~hnoh~,:~, (Cambridge
of the present
each. the deve!opmcnt
(141
Focusing
Perspecrrces
During mated
of Technological
and
Ber~~ven
Prows
D.C..
(Na :ional
1973 j,
1970. the year when the TAT-5
cable uas
laid across :he Atlantic.
1171
The
data
‘l’ans
were obtained
of Goddard
expenditures pond
amounted
ECHO.
SYNCOM. and
experiments.
Tllr
not by NASA.
MRI
communications htes amounted Interview Center,
1191 1201
Alton
October
1978.
EC ,won,,c .\ , Krvue
t Novcmbcr.
C~unuclrennt~
‘f’tc~,,,rnn,ryuc~
I
I (4,
York.
[22]
1969) 570.-579.
Global [23]
TELSTAR
preceded
[24]
H.
An
Wood
Satellite
$29 and
of delay
spending
on
and G ciatelSpace
and
echo
(see section
rrdunda.ncy
on
Fucrhfres
in our
Flight the
I).
Policy. May
alternative and C.
.Srudr
197 I). c;il
of
in a sense we takt, the into
account
fit *as
Communications. Systems Conference, Decision,
6th
is $30.000.
Effect \eness
COMSAT
Corp.;
September
and Cables AIAA
hlontreal.
in
paper 1975.
in Intrrcon-
Communications Canada,
Cornmumcations
and the Problem
.ree B.
Cost
F. 26th Congress.
Role of Satellites
B. Owen. The lcternational TAT-6
figure
Reher,
Communications.
The
tinental
Rosen, July. 197X. to the general market,
include
paid by DOD
Goddard
of 1aunc.h failure
at the I.A.
Satellite
u\e and not a\allable
frequency
S. Ramji,
with Dr. H. Rosen. July, 1975. I hut was only in limited
of
costs although
presented
with Dr.H.
INTELSAT
SYNCOM
hasis. See Iniernutionul
however,
See [3]. p. 56.
[‘dl Inter\ll,w Interview
I ]‘)I [lrl
Jones
the effects
investment
Edelson.
1963).
the
and support%
zero).
IX1 H Ro\en. Synchronous C‘ommunrcat~on
about
exclude,
actual
as and
the costs of
to the ATS-F
of Telecommunications
\atellitr 171 1l.c‘. kludler and J.E. Tilron. Rrscarch .md De~elopmenr (‘oats as a Barrier to Entr). The C‘ut. udrtrn Journul (I/
prier
million.
to $137 million.
On a present-value We
of
presumably
those he-
distributed
$43.6
include
of voice communication>
(Office
I?]1
million.
reports that total NASA
satellites
with
Especially quality
costs
stations
proJected
(inc’.lding
RELAY.
Costs
Development
Total
launch vehicle. ground operations
million on ground
[‘Xl
to $130.7
million.
Project
Center.
programs
$19 million.
$68
:.pacecraft,
Ihe
Flight
on the three
1965)
follows:
from
Space
1976.
Industry.
of Regulated
th:
Uiligopoly
(Departmtxt July.
of Ec~~~~rnrc.s. St.lnf~~rd I:n!\t
rvt!.
reb 14
lY76).
[?S] If (i) doeh lwt hold then pari 01’ the direct WC ascribe
to the
p<,st-h.s.c.t.
~cchnc~logy.
[Zh] Over
and
demand [27] This
hrkond
the
effects
for telephone
is because
rather
h.a.c.1. \\oulil
circuits
really
CI~ the pra
we calculate
sa,ing:, cir,xith.
life for B new
design life hetaecn technology:
01
ela>tlclt~
111
rouie.
per ?I)-\ear
circuit
issue here is thr allocat~cw 1.11the rexcwrc’c’
savings from substituting design
vl~lcll
in the mam Atlantic
than savings per I-year
[2X] The theoretical
bcncfit\
he the rc\ult
an older trchnol<:g,
~echnolngq
wth
with ;I I~wg
;L re ativel!
two htagcs in the hibtor.
the !wccline
technclney
ah~~rt
01 the ncu
and the post-baseline
improvements. 1291 For
the definition
Ew7orm
Grcwrir
Cambridge. [30]
See T&le
of maJor of
tvla!~.
lY7l)
6. which
is taken
have hecome re!-cant
[32]
100 tears
major
innovatior~s.
for the full impact
[33)
For example. If satellite time).
a generation
meas
as the
It is not surprihin:.
to tha
tllc markrt lo;4
work.
cial communications
therefore.
on rezourcc1,
need. Benefits
should
such a netal
rhat we hate
nc, rc;ll
trchnol-
.stutl;~. Ior cxsmplc.
rccuwmic
stawn5
inlpact.
of C’0MISA.I
Thc\e
:
grw
arrived
and channel capdcitb ): ae
of firms augmented were subsequently markets
by th& applied
firms
intcrxtlt)li to commrr-
are also reavded.
However.
issues for ;I ~1s~. benefit
;lnJlx\l\
not yet been addwaed. at
WNCCM
the subsequent applications de\rloped
Inth ~,f
etc. Case !.tudie!. of jww trchn~)-
[36] This wab the case not only with respect to the xxic solution
from Job.
found
commumcatlon\
The MKI
.md revenues
the basic methodological have apparently
un:, ~tlhflcd nwd
This may be il \‘tx!I’ difficult
for haroware.
capabilities
with NASA
r.itc ~11
program
value of mee!lng
of direct
tb : bystem (ground
;L‘fall’
it Dale> not saw
ory ;b u major ib..wvation. invcslments
he rc-
1~1;I region fcv the t”lr\t
seriiccs
analcsilr of satellite
rcterb to mesure:
for
~)f current
two ma:, *till
a prevxwly
directly
society’s point (>f view
clude
applicatior~s w
t~rc\h
Even all~luing
in the b.s.c.t.
by definition
he csrimated
it:slf.
to bc felt in the cccxxwiy.
telephone
devoted
Add~tl<~~.~l
4tilger
as a result of the ATS
technology
then
cxt-hcnefil
[3] stud!.
should at least he artrihutrll
(e.g.. providing
I’rcr.
engine. few cuample.
in the various
tc~ its investment
previously
from
aam
quired
[34]
cr\lty
333.
to manifest
lead timts
For this NASA
me S. Ku/n~t\. Iin
since.
shorter
return
(iSI
pp. 314
The full impact of Walt’s more than
f Harvard
pal ential or at vmou~
apphcatlons. [3l]
innovation
h'trrrons
hut ail,,> ulth
K Sr 11 (4TS)
in the latter were :llso located
and had immediate
commerci.ll
dr~_rn
rqxct
ICI
The capahilirle*. 111011: con~ract~v implic,ltions.
It I\
Government policy, innovation economic growth Lessons from a study of satellite communications
and
*
Morris TEU BAL
Edward STEINMUELLER Sumford lJnr~>ersiy, Stanford, CA 934W. Final
version
received
February
ll. .“.A
1981
The pnprr analyzes NASA’s imoivement in the de\-felopment of satellite communications technology. It begins by a historical acc( unt of the mairl developments which culminated into first commercialization of the technology in 1965. The description
highlights
It also provides
NASA’s
role iil accelerating
important
background
ing the COSIS of NASA’s
involvement
this process.
information and some
for measuraspects
of the
benerits. namely part of the ‘direcl’ benefits achieved in the initial applicalions segment (transatlantic voice communications). The paper then analyzes a number for the success of NASA’s involvement. the efficiency
of factors responsible both with respxt to
‘baseline’ technology
of the
arrived
at and with
respect to the transition from early R & D to commercialization. A comparison is also made with othrr less successful cases of governmeni
mtervention
to promote
new technologies.
’ Funds for the support of this study have been the NASA-AMES Research Center, Mofff:tt fornia, under Interchange No. NCA2-OR7455815. We are especially and
grateful
help in defining
Federal taking
R ,Sr D and satellite
to Harry
communications
has also given generously advice grateful.
and Our
to Harold
a project
encouragement. thanks
Hornby
allocated 5:, Field, Califor his advice
on the economic
impact
Goett
suggested
for
having
as a case study.
Harry
of hi,; ime and provided
of
Goett
important
Finr all tr’lis we are extremely
to P. Bar:;ellini,
L. Jaffe.
A. Jones
and
Professor Lusil,:nan for their cooperation a+ various stages of our work and to J. White. H. Halley. G. Allen Smith. D. Smith, J. Har., and Dr. R.T. Jones who projfided useful background inf xmation on the activities and Impacts of the National Aeroniautics and Space Administration. We appreciate the comments gested improvements
of two anonymous in an earlier draft.
Research Policy 1t (1982) North-Holland Publishing
referees
who
sug-
271-287 Compaq
0048-7333/&2/(iOOO-0000/$02.75
,0 1982 North-Holland
1. lntroductioa The path leading to the maturity of industrial sectors is generally associated with a deceleration in their rates of growth. This has been pointed out almost 50 years ago by Simon Kuzmts. An important implication of this trend is that any economy wishing to maintain its uggrt>glIfe growth rate should be able !o generate a continuous flow of new industries [ 11. Federal R Rr D may stimulate I,his process by inducing the private sector to undertake radical innovations which would other\viAe Ilot be undertaken or who:.e introduction lvould be seriously delayed. The red:lction in the technological and in the market risk of the innovations. consequent to Federal R & D programs. ma); counteract the forces responsible for deceleration. including the observed tendency of some established industries to follow an evolutionary rather than a revolutionary parth of technological drvel. opment. Our purpose; here is to illustrate .cnd give somt’ structure to the above in the context of and basec on the experience with satellite communication> In addition, we will attempt to measure somr’ aspects of the social benefits derived from this neu industry and to address the question of the chart of these benefits which may be attributable to NASA. The report is organized in three sections. Section 2 s a historical description of technola$ cal developm!:nts in communications satellites. It:. in tt:t emphasis is on f‘ie efforts whicl, culminated first comrr;erciaiization of the technology in !%5.
is made to &scribe the events in the c~~~tcr;t of our knolvledgc of innovation processes ,n genrral and 10 describe the activities and irnp;~ts of NASA. Section 3 addresses the issue of the benefits to society from NASA’s efforts in :,;ltcllitc communications. A dlstinc.ion is propo,ed heti\,ecn a ‘baseline’ communif:ation satellitc tcchq~logy and subsequent developments. An ;~rgumcnt is put to attribute ali th:: ec.)nomic hencfith of the former to NASA. A ~zc\mputalion of Finally, part of these bcncfits is al50 presented. Sectic,n 4 discusses some of the i:.surs which emerge
.At
from
~lctcfnpt
th,lr ca\e study.
2. A historical dc~elopment
and techuologicd
of communications
suney
of
the
satellites
The development of communication satellite technology and NASA’s involvement in the area can be broadly divided into three stage!;; invention, demonstration of feasibility. and commercial development. The invention stage includes a series of critical experiments which determined that no physical barriers to orbital transmission and reception of signals existed. In thr demonstration of feasibility stage a wide variety of system designs were tested with important knowledge and skillcreating implications for emerging supply companies such as Hughes and GTF1. Finally, with the development of the quasi-,,rivate communications companies COMSAT and INTELSAT, commercial users undertook the contracting of commercial satellite communications systems and a variety of ground StatioIi installations. a “reduction to pract:ct” of the new technology. NASA played an active role throughout its period of involvement. 1958 till :he early 1970s. in the development of the c~~mmuni~ation satellite technology by providing a research and development infrastructure and b? contracting for operating systems which steadil) increased in capabilrties and performance. NASA’s research and development decision making process invol+~ed a series of committees and solicited proposals which sought to define the major technological problems at each stage of the development 3rocess and to plan a series of design research .asks which would salve these problems. This ln‘rastructure also was a basis for determining the ialure Ol’ contract specifications when sp.;cific sysTerns were developed thus coordinating tc~chnologi-
cal policy with implementation. Communications satellites were vi:iualized in the 1950s as an alternative technology for coping with a basic constraint of terrestrial telecommunications, the curvature of the Earth. The Zarth’s curvature is a barrier because the propagation of electromagnetic radiation is linear. Before 1960 the available solutions were direct connection (undersea cables or a series of “links” on land) or high frequency radio transmission which utilizeui the reflectivity of the ionosphere to “bounce” signals over the horizon. The latter phenomenon of ionospheric reflectivity provided a basis for concenl about viability of satellite signal transmission hecause of the uncertainty of how efficiently signals could be sent through upper atmosphere layers. The SCORE launch demonstrated (ha! signals could indeed be transmitted and received with reasonable efficiency from an orbital position [2]. The next step in experimenting with the idea of satellite communications was the development of a passive reflector which would serve the same purpose as ionospheric reflection with more efficiency and reliability. The problems of cfficiencq aqd reliability had limited the growth oI intercontinental radio communications.
The ECHO program was based on this principle of a “passive” communications satellite. ECHO did provide ;I reliable means of “bouncing” signals over the horizon. However, ECHO by no means solved the problem of efficiency. ECHO proved thst the passive sate!lite approach led to a drastic limitation of power available to the receiving station because of the dispersion of transmitted and refll:c.ted siglnals. III the ECHO experiment OIIIJ one part ir: 10’” of the transmitted power (10 kW) wa> rlvailuble lo the receiving anttmna [2]. Oi COUTS~this limitation was known before ECHO’s launcn and ,the development of “active ’ satellite s4ystems was presumed to be the only really viable means of achieving substantial communicalions capability. The “active” communications satellite receives a signal and retransmits an amplified facsimile of the signal (usually with a frequent*? shift) [2]. The problems of active satellite dt+gn ar:‘ analogous t J designing teleconlii~ullic;Itic,ns links for terrestrial microwave systems uith the impor, ant added problems of the space envin:n-
mcnt.
weight constraints.
impossibilitv
power
Ilmitati~w~.
the fundamental
elements of NASA’s
demonstru-
(ion of a feasible satellite communications ogy and determined first
of NASA’s
mxj!;ior satellite programs,
could
satellite
NASA
was granted
authority
Defense
Department
design
not in
agrt;went
1961 to allot satellite
rese,rch
prohibited
1960
trolling
to \+orh
technological
[3]. Defrnce hrcauw
agreement abridged in
of
commune-
of the a.!iificult\ of ~cln-
acce~ to knowledge of >*Jch private]? demonstrated
n~logy.
by pioltecring
commercinl
by a great
occurred without
NASA
speculation
parties
to
\vould have
is of course counter-fact-
but
does
point
NASA/DOD
relations
may
to
InIlitary
dr\&pmcnt
exclusively
potential5
many
What
development.
Jc-
the tech-
the commercial
and this led tc>pressure
ual
in
terri-
interest.\ ma> hrtive
development
veloped hystemh. NASA.
allow
until
to engage in i:e’~~~nc’hroliou\
+.ate
cations satell~trs
on
proceed
had to be further
NASA
of the
U’orb
tory by reviwng in 1958 DOD/NASA [3]. This
technol-
the design problems
active
formerly
end
of maintenance. These pr~,hlemz uuc
have
out
hridgcd of
th;:t
;I barrio CC~IWI~LIII~-
cations satellites.
-.? .’ . RELA )’ The
RELA”.’
prt>gram .~uccrssfull~ pl,wwC’d
wrirs
of
na;tjoi
fil,\t
uses
of
innnvat1ons
Wave
Trclveling
a number
!+.‘Ctz.
of
da1 ;I transmitted,
improvements
including
[4]. The
fi3ts
ground
in
station
RELAY
other
the
0ptimiLation
subsystem
derstanding
as
of the radiation
space
environment
f,tud
Report
681 -6X7). Technical transmitter
(Picknrd
ON the
trchnrque data
communicnkn
well
and
enhancing
as
[4] pp.
1 I 1. 1 15 and
Rciclq~ 1 Froy~u~z characteristic5
SUJ dards (Pickard
[4] pp.
of the satellite \\ith cxistlnp
[4] pp. 116. I IS).
111sptte of serior .; problems kvith the pwtrr and
3
last
that
the TWT
container, mental this ;iswss
minute
the
discoveq
which
system
nrcessitatrd
as designed operate in a pressurized
RELAY
I did
The
goals.
progrnm
un-
(high energ? partii.lt’I
Lvert‘ chosen to conform
international
af
I misbion \{;I> de-
of
design
in
t>pch
sIgned to provide a great deal of sngintwing allwving
;I
r>f the
tube amplifiers
importan!
and
ant
should iiccL1rac~
by determining
IIUSI
accomplish of
dJt,r
he strzwd. of
il:.
cqwr1-
accumulated It \
rrhroadca~ting
the exact deviation\
b\
poaihlc
tk\
: .‘!I1 quit (‘1 rrrcri\ed
launch. Tht: basic problem of orbital placement W;IX solved in spite of thi4 failure: prclund :,tation tracking rrj.ealrd SYNCOM i had ci nearly idcal orhit. The failure of SYNCOM I to sc’r\‘c its
()j~e critical limitation of the ll~~~-~~ll~l~~~~ll~~~~ design of Io\ver pon’cr. such as RELAY I. \\:I, 11-1~neccssrtv for tracking (moveable) antennas. Thi> nccesssrily limited the number of facilitics rvhich could reliably receive ~:xttXded COIlln~unicatiom hecause of the high crtat of each staticjn. It also dictated a very high investment in 55atellitr systems if continuous comniun*cations were to ht2 an objecti\,e since it implied a siring of \atellitrs so that at least one sa,cllitc would always tbc ahove the relcvnnt receiving area. For these reasons, the po>sibility of a major re-de’ ign of the basic satellite-ground station system wa$ proposed by Dr. H. Rosen of Hughes [a]. Hughes was un:ible to sell this idea to the Department of Defen.,e or any corporation large cnouph to support the development costs beyond the exploratory stage accomplished at Hughes [9]. We may speculate that the major reason for the difficulty of selling the Hughes system was the risk of an entirely new system when a known. albeit expenGve. solution was knolvn to exist. It is also important that J. Pierce. of Bell Laboratorics expressed severe criticisms of the proposed geosynchronous :.atcJiite because its altitude would entail a delay in c ,nlrrrunications of 0.46 seconds which Pierce ‘>ellrved detrl.nental to “quality” of tclrcommunication service. However, NASA finally ~‘~1sable to support research in the area which led io the SYNC’OM I. In order to do this NASA had to obtain another agreement with DOD concerning gee-synchronous satellites. an area which had previously been the exclusive domain of DOD by agreement with NASA. Authorization was achieved in 1961 permitting NASA and Hughes to joint11 dcvclo;, the SYNCOM I satellite (see [3] p. 12). ‘fhe fundamental design problems of achieving :I 4vnchronous c>rhit and broadcc:s:ing a continuous higna1 to Earth were solved by Rosen and his rchearch group at Hughes. NASA awarded a controt to Hughes in Aqust 1961 leading to the February 1963 launch of SYNCOM I (see [3] p. 14). L’nfortunatelv a n trogen tank explosion destrovcd the con;munic;ltions capahilt\ during
x:lleIIite
communications purposes, in spite of an expenditure of $20 million to develop. m;:nbfacture, and laurch the satellite, would have been a severe blow to the development of an exclusively private satellite indu;tr!,. Because such risks were known b) NASA and direct payback was not an issue in the calculus of mission decision, NASA prepared and launched the backup satellite SYNCOM II in July of 1963 [3]. SYNCOM II was not designed to he a truly geostationary satellite hut rather to maintain an orbit which caused it to move a distanr,: of 33 degrees north and sot‘th of a,id perpendicular to the equator (see [3] p. 16). Midwest Research Institute has catalogued a long list of improvements incorporated in the SY NCOM I.1 program including technologies for transfer orbit, antenna array, automatic station keeping, and a variety of improvements in power and communications subsystems (see [3] p. 15 - 16). I .le major experimental purpose of SYNCOM II wa: to establish the feasibility of the semi-station.:ry orbit and provide engineering data on c:,mmunicatlons design SYNCOM II was so suecrssful in esrablishing the viability af synchronous satellites tha,: civilian communications satellite systems have subsequently uniformly heen of ‘he svnchronous design. Back in 1961. the viahilit.? of i synchrr;notus orhit solution was severely doubted. The ADVENT program, an Army synchronous satellite system. had been running into difficulties which eventually led to its demise. Thus. in the context of 1’36\, if SYNC’OM had not beer1 successful there is every reason to believe th&t the present predominant technology for communications satellit’e orbits. synchronous orbits. would have emerged at a much later date if at all [IO]. This success v$as the basis for taking mc:h of the risk out of d,:crloping commercial communication satellites. Tile SYNCOM Ii1 satellite. which achieved a near perfect geo stationary orbit in August of 1’464 was followed less than one year later byi INTELSAT I, the first commercial communications satellite [ 1 I]. The SYNCOM III achieved a truly geostationary orbit and demonstrated the technology \k:‘ automatic station keeping which WPS another link in the development of synchronous satellites. I’~u
:lapecth 0f thi5 station-keeping ?cwtant
further
1~
capability
dcwlopmcnts.
ground Iracking w25 inferior
in accuracy 1(.>in-orhit
btation keeping and the diwwq “ tri-axialiry,”
of the Iiarlh’h
pear shapcdnrss.
Lvhich rnrani
impulse power to preserve stationarity cantly less than originally cxpect::tions. mere
accurate than
position
the
u’as signifi-
anticipated.
on-board position
iuwxpected
wcre im-
the dihcc?\.cr\that
Contrlrrv
to
sensing \vas much
terrestrial
observarion.
accuracy of onhoard
sensing 2nd correction.
station
The
keeping.
set a standard
of
accuracy which would for several Fears focus technical eff,ort This
to improve
phrnnwa-wn
ground
aspect c>f technological terms
the 11llure of focusing inane;‘.
The
mtlchaniams
hy
potrntial
dards and specifications a pnrtiwlar
tracking.
change [ 121. In cconcmic
they provide a clear aandard quality
station
of focusing; is also an important
system
is that
which to mwsurc
user can use htan-
IO relate the cost of using
to its capabilities,
The
tatter
development ( the discovery of the pear-shapcdness of
Earth
(though
propriately
Ihe
analogy
is
more
ap-
an over ripe peach that has been picked
up firmly
in the horthern
hemisphere).
ample cf a rare but significant gineering.
the discovery
model. While
does not benefit
in en-
of a new physiclri
ple white engaged in solving well-defined
is an cx-
happening problems
princi-
txithin
much engineering
from a scientific
;1
\vorh
model (the phr-
nomena tire 100 complex to he completcl~
sprci-
fied or too new for thcorv to have caught up \\ith practice). l~rce
it is somewhat
modifk~tions
in
rare
for
enginwring
10
the models it does ust’. In
t.lis case the technology of geosynchoronous
satcl-
I~.es was a more attractive
option when thl: knowl-
edge about
state of
the physical
changed by empirical standards.
and specification
communications
the world
observation.
satellite
By
~~3s
1964.
of ;I particular
the
type of
were set and the major
questions
facing the commercial
the costs
they wwld
face in
drv&prrs
\\crc
implementing
the
technology rather than developing i::.. ‘The pattern of incremental earlier The
was apparent
development
W:;ve Tube
of incremental versus
2s
Traveling
9s well as changes aimed at
the specilic cntastrophc of SYNCOM
mad,e S),‘NCOM 111; solar
noted
program.
of a non-pressurized
amplifier
eliminating
improvrmer,t
in the SYNCOM
II an improved satellite. changes occurred nith
power in
collectors
SYNCOM
delivrrcd
II. bandwidth
I
A series
SYNCOM 32.5
~valls
went from
The contributions of the ATS program to techprogress in satellite communications arcs numel~ous and dislributed over a considerable number ol ~pecialily areas. Table ! itemizes sonic of these contributions. The specific intent of the .ATS program LV;IS tCJ explore IW.V technologies for application to later aatcllites. Among these techfor multiple ac_Y)rb. nologies 1ver~2 capabilities aircraft commLlnication. spin scan cameras (color ;md black and Lvhite). position \cnsing. operation in IIC’I\ frequency bands. and improvements in inl‘~;rm,itin;n codrng tichniqut’ (see 131 p. 23). ‘The I973 ATS-6 satellite ua5 an impctrtant hrcaktrhough 111achieving high orbital broadcast po\\cr and dralilutically reducing the size and cost of t:artt-;’ ha.4cs-I receivers [ 141. no!ogicnl
‘l‘iw most important observation ahout “iese I :chnical imprc>\~cments is that some of them “p;~ce” the developments in commercial satellite technology:. That is. NASA programs generalfiy led III the development of the major techn~~logical xdu:icvis ;o commercial hatrllite problems. III tahltl 2 wc have comparccl a series (?I” such major design solutions transfcr:cd from NXSA contract to commercial hatellite s\,stems (often constructed h\. the same contractorsi (see [3]. pp. 47--4X). The impc)rlance of NASA’s t~:chnolopical lr:~d is twofold. First. NASA had a :4gnificant id in cspericncc over the commercial sector and \%5’aspursuing
<)hjrctivrs 0: a more icchnological character (thus NASA was pl:rhaps less constrained by cost considrrations), Second, NASA appears to have adopted an expiicit policy of taking relatively large risks in order to extend technical capability whereas user firms such as COMSAT have been more cautious in their explorations of new technology. tending to make improvements within existing system design. The latter point is particularly relevant for current NAL;A policy.
3. NASA’s
contribution:
Cost-benefit
analysis
The history of satellite communicatir;ns technology (s.c.t.) a::id of NASA’s role suggests that it may be useful t,;, distinguish between two periods: the period prior to the first commercialization of s.c.t. in 1965 and the period after 1965 1151. We will argue that NASA’s contribution was decisice in the first period and therefore that the direct benefits from the s.c.t. of 1965 - henceforth termed the baseline satellite communications technology, h.s.c.t. - should be Jui!~ attributed to NASA. A preliminary calculation of these direct benefits, for the first sub-market telephony between the U.S. and Europe ,Nill follow. After 1965, the direct contribution of NASA seems to be rather small. rt&rtivc to its contribution in the previous period and probably tc the contribution of the companies directly participating in the commercial exploitation of S.C.I. N.ISA’s contribution is basically an indirect one - <)f having been responsible for the b.s.c.t.. upon wllich the dramatic improvements in s.c.t. occurred. ;l process which enabled rhe grad-
ual diffusion
of this technology
among
;in
increas-
ingly wide spectrum of applications. It ivill he argued that existing co5t benefit analIsis is. I-J\ it.si’lf, inadequate to evaluate these bencfit3. the reason being our lack of an adequate conceptual framework which will consider (I) the timing of introduction of new technologies by the private
sectnr. (2) the competitive reaction of existing technologies to the threat:; posed by new rechnologies: and (3) the external economies ,Nhich any application pro\ ides to those firms engaged in subsequent
applications.
Without NAC A’s involvemezi. ~hr introduction of the b.s.c.t. u .)u/d have been delayed. at Ieast br:,ond the date where its efficiency was surpahJscd by that of the alternative cable technology [ 161. The technological history of NASA’s involvement in s.c.t.. is proof of the criticality of this involvement for the emergence of the b.s.c.t. The opinion of experts prior to NASA’s involvement Land after failure of the AD\,‘ENT program was ovek,whelmingiy pessimistic about rhs prospects of a commerclaliy viable synchronous satellite communications system. The MRI study (carried out in 1470) si,ltes: “Only slightly more than 10 year!, ago. many experts had serious doubts that: satellites could survive in space. and operate long enough to paw out; th,e quality of satellite communications transmissions would bt: acceptable; and that the cc .t of satellite systems would be competitive wi’h traditional earth-based communication.”
131 This outlook was lar$,ely responsible for Dr. Harold Rosen’s inability to “sell” the idea of a synchronous satellite to either a military or a civilian ager-t; NASA’s taking over of the project was essential for the successful development of s.c.t.. at least during the 1960s [IO]. Some quantitative evidence on expenditures on R & D and engineering efforts also bears upon the previous conclusion. NASA’s expenditures on s.c.t. between 1960 and 1965 dwarf that of any other agency or firm potentially interested in a viable commercial system. Hughes’ accumulated expenditures prior to NASA’s taking over the synchronous satellite project amounted to approximately I million dollars [IO]. The accumulated expenditure of
SYNC’OM
ATS-I
ATS-I
SYNC‘OM
(Altilde
(Low encrg~
(Electronic
( Broadband
hcnwrs)
proton
phased array)
25 Milr)
ATS-I
damape)
ATS-III
(
(Spin ~a~,lhill-
(Mechanically
ATS-III
/ation)
&spun
(Dual
II
array)
III
ATS-I moclc)
(PVIWICI ccrn~rol; (Polang Irtrirude) SYNCOM
III
AI-S-i
SR&7 power
II
(Tri axdlity
(RF
and pr:ivity
hirndling)
(Shapd
pcltellllal)
(RFI
crwr3gc)
problem;
(I Ical
SK&T (High
SK&T arc’2
output
TWTs)
pipr
cooling) A?%F&G
(Low
ATS-F thruhr
Al%F&G power
arrays)
jets)
SK%‘1
(30 II deploy-
ATS-V
ahlc array)
(200 \\a11
(Slip rings)
SR&T (Flcxrhlc
(Hi@,
TWT
hod\
I2 GH,)
CffCClh)
(Multipactmg high power
PF
components) .AT:s-lll
SYNC‘OM
ATS-I-
ATS-I
III
ATS-III (On
hoard
processing) (40 watl L band)
tion ant! maintenance cos:ts, administration costs, ground station investment costs (fol the salellite c~nly). tails (for ;*ahk onI\,). and possibly profits 2nd taxes. Lashc j UIC~O~en’s figures for tht: cha ‘e of 5atrllite inve tment costs over tota: cost; for Intellsut were 4 percent and 43 percent for the TAT-5 and TA.1 ‘-6, respectively [2U]. There ‘ore. use of satellite investment costs and cable in\ ‘tment costs in ou,’ calculation is ~_~~~bably ind,cative of the relatio iship between total satellite costs and total cable costs [Zl].
(2) Period:
The
relevant
period
ends
witk the
mlnimum of two dates - the expected data of introduction of the b.s.c.t.. under the assumption of no NASA involvement, and the actual daie when Cable Technology in use became more efficient than the b.s.c.t. Table 3 qhows the relative efficiencies of the various TAT cables. The design life of these cirbles is 20 year!. The efficiency of the INTELSAT I technology is given by the figures below [22!: --~_ Investment, $9 000.000 InvestrrLt cost per Design life. 1.5 years capacity circuit, Circuit capacity. 240 per Fetrr, $25.000 _ _ _ _ _ _ _ _ _ ._ _ _ _ _ _ _ _ _, _ _ _ _ _
.~_.__ SpJcc
-__.__ lxth
wgmcnt
wgnwnt
--. Channel
Down-link
ground-station
C’p-!ink
~~rcwnd-~tatt~~n
capacity
frequerq
tranzmlt
frrquenck
rt’ca\c
antenna
SYIWOM
II & 111
AT!+I (Buvlding
SYNCUM
II & III
feed .)
ATS-I
A-E-V block)
(C‘a5wgrdrn
dntrnnd
(Millimeter
waves)
ATS-III
( PWIJC~mon~~pulwt
(C‘hannrliration)
SRJrT
AX-F
ATS-V
SK&T
II (SHF and
ATS-I’
ATS-I mcler
(Sm311 and
mrlli-
tranqxwtahle)
*ilrt
propagati’on)
ATS- I
SYNC-Oh1
AT%.-III
AT-S-III
AT!;- F
ATS-F
(\‘HFI
(L’HFI (L-hand)
SYNC’OXZ III ATS-I (AKINC’I A N-III (OfIt!,
To find the present value of the investment cost per satellite capacity circuit for a 20-year period the cost figure which has to be compared with unit circuit cable costs of the last column of table 3 we take the PV of $25.000 per yca~ for a period of 20 years discounted at 10 perlzent interest rate, PVS: PVS = 25,000
1 - U/l.lP’ 0.1 i
I,
_ 213 ooo * .
.\‘I S-i’
_____Ysdr
Lengtlh (nautical
Inilial Invest-
de\)
mcnt
In~edn-13~8
C’ircuir Upacllr
cm1 p:r ;lllcrn.ll; circuil
__ 1956 I Y5Y lY63 lYh5 I’)70 I’)76
2.2hX 2.531
44.9 42.0
3.514 3.509
46.4
3.600
I9 I .o 2YO.O
”
(4) Unit resource savings: Point (ii) above implies [26] that 0ur calculations implicity ,sre made on the assumption that cables are perfectly divisible in capacity while indivisible in lifetime. This is unrealistic but enables us to avoid the problem of having to decide the titning of introducti’on of the
Tahlc4 SaLc!iite circuits .-- U.S. ~Europe --- ~--_-----_-
,!elcphony
”
- _-
! 965 1970. WC dcL+drd to calculate reWurce sav~ngb over the volume of satellite trafiic in ZISC r,ither than over satellite circuit cq~~ir~~. The former would bc closer to the amount that TAT-4 cables would have I.O substitute had the h.s.c.t. not been available. The calculation based on satellite circuit capacity is also made for reference purpo~1~‘s.Some additional assumptions are implied when using this measure: (i) Satellite circuits in ~-se during the period wou!d not be substantially low ‘r had no improvements beyond the b.s.c.t. occured; (ii) the additional cable circuits of the TAT-4 type that would be installed in the absence of the b.x.c.t. are roughly equal to the satellite circuits actually used during the period [25].
XX0 X75
4X 4X
46.0 X7.0
3.44 I 3.692
IYX5 h
--
____
__.
_-_
141 i3X
329
X45 4.r)w
IO3 4x
I ?.rNO
333
?.4 h
h
-
--
addition;:; TAT-4 tcchnoi~~gy cables which would have been laid had Ihe b.s.c.t. not become available. In any case, it is doubtful whether our calculations would have bel:n significantly altered had that decision-making been explicitly taken into account. Under our assumptions, 20-year circuit resource savings, discounted, equals the difference between: (a) unit circuits costs with TAT-4 technology. which are paid at the time the additional cable would be instai!ed. and (b) PVs = 213.000. This amounts to $120.1’;00.
The Culdution: The above elements of analysis enable us to compute the direct impact of NASA’s involvement in satellite communications technology in its first commercial application: telephony along the U.S. -Europe route. Table 5 indicates the procedure followed. Note that the resources saved in any particular year depend on the additional satellite circuits used or installed during that year, and not on the absolute number 0.’ circuits [27]. The present value of the resources saved is
uh-market ---
I965
1966
1967
64 64
72 8
165 x7
242 71
464 222
240 240
240 0
240 0
I.500 1,260
1.500
---
-~___
lY6X
~~-.--
1969
I970
0
5cxl Yb 6.000 3.470
$49.5 million when the calculation is based ~jn satellite circuits in use during the period. and $421.23 million when it is based on capacity. $49.5 million is, in our opinion, a lower bound to the resources saved from the first application of the b.s.c.t. There are a number of factors which would raise the figure: (a) the assumption that cable technology iv;ts independent of satellite technology. Experience tells US that slevelopments in cable technology were consider:.Sly accelerated by the introduction of satellite techlaology. This would tend to lengthen tbc period were the benefits from the b.s.c.t. should bt computed. ‘b) the unit circuit savings from the availabi!ity cf the b.s.c.t. are higher than computed due to the Lower design life of satellites relative to cables. Thus, after 1.5 years of life. a b.s.c.t. circuit could be substituted for a more efficient satellite technology, and so on throughout the 20 years of cl;ble life. Part of these. additional savings should be attributed to the b.s.c.t. because they would have occurred even without additional R & D and engineering resources explicitly allocated to improve the b.s.c.t., i.e.. through oper;tting experience. learning by doing in the producti,?n of hardware. and unpriced externalities received irom other sectors 1281. In our opinion, both of these I’acturs certainly outweigh by far an:, possible over-estimate in the
\,olume c>f satellite circu>th il: use \\ hich \\~~ld have been substituted b!. l.ablch in the ;th.\cncc of the
b.s.c.t.
The direct benefits front introducing thrs IJ.LC.I. the IL.!% f:uropc teleinto its first application I;hrmy sub-market. reprryl:nt , n import;mt share of :.tll the NASA expenditures itXading IO thih frchnolt qy. This share is :\t lea\t ;I third. and prohabl> much more. This is a rctnarkut~le achievement for the foilowing reasons: ( I() Satellite communications technology is a m;L_,or technoloq or innovation [29] ‘\I post-World War II indtl- :rial society. Yt is sufficient to look at the set of .wttiaE and potential applications of this technology in order to realize this fact (30). (2) The full impact of thih (like any) rnajcjr technology on econorn! (and sctciety) will makt itself felt only after ;I re;l>ol ahlb long period of time !3 I]. The direct impact anal> XJ previously refers orply to one sub-market tort?spending to one ;ipplication. i.e.. part of interniltional telephone trunklng. the first application &own in table 6. We doubt that we mav find caxe\ where the first direct impact of the huselinte tec!lnological level of a major innovation Lovered one third or one half of the co,:,ts lvithin h year>. NASA’s over-all contribution ni;b\ 1~ di\ &tf into three parts:
Data coll~~c.tion and relay High quality.
high
speed fnc:imilr One-wq
Satellite-lo,3atellile rcLi\
de@ tal
data distribution; financial Time
sharing
service.r
Meetin@ and polling Information
networks
Law and justice MedIcal and scientific:
(1) The resource savings due to the b.s.c.t..
in the first sub-market and in subsequent sub-markets or applications penetrated by it. The share of ~~111 resource savings due to (21 post-b.s.c.t. whicll >ilould i)e attributal-it to NASA. (3) The share of the value to society derived from the satisfaction of previously unmet needs. The first part is calculable and quantitative. it probably does not go very much beyond the international telephony sub-market because improvements beyond the baseline technology were essential for most of the subsequent diffusions of s.c.t. Cost-benefit analysis can be appropriately used here. The second and third components are ex,. tremziy difficult to calculate for the following reasons: (a) The technology beyond the b.s.c.t. is dut: to the joint action of the following factors 01’
agents: NASA as the agent responsible for the introduction of the b.s.c.t. upon which subsequent impr0vemen.s are based [32]. NASA as a contributory agent to post-b.s.c.t. [33]. commercial firms. INTELSAT and COMSAT, as contributors to post-b.s.c.t. (b) The diffusion of p3st-b.s.c.t. within and across sub-markets and applications depends 031 technology adoption and switching decisions of prikate firms. These decisions ai:e influenced by the pattern of unpriced benefits (externalities) generated in the various applications, especially the initial ones. Moreover, the third component requires some radically new roois or analysis. presumably a theory of needs [34]. Our empirical and theoretical knowledge of these processes is slight. This kaobvledge is essential for evaluating the impact of n?trjor innovations and the possible share which may be a.ttributabie
4. ksues emerging
from
kASA’s
imolvement
in
C.S. technology
Another aspect of NASA’\ acti\lt) concrlrn* the accumulation of J bnt9s ledge hd\e for cnginccrtng de\@. Tbi\ is an cffectl\c \\+I\ of stimuIat.ng I!X coml~lelcialszatinn of 3 techncllogv xincc 11 rn.i\
con:riderahl> rt!dJce the wart c>f finding AI (~~ptiSUCCC~~in the transition from earl, R Sr II (and baielinc technol ‘gy development) to cor,rmrrcialization can be iIscribed to LL numher of factor>. First. a suhsta~ tial portion of the R Br D and pr~~totypr development and building was prr-
formed by subcontractors such as Hughes which subsequently supplied the first (and subsequent) user(s) [36J. To a significant extent there was no need for explicitly transferring the design and manufacturing oapabilitics from Government to c#Jmmericai use. Second, experimentation by NASA of a variety of different satellite systems prior to commercialization led to a cost effective first commercialization of this major new tcchnoiJ’gY. !n this respect it is highly significant that NASA attemptetl C.S. programs of its own, over and beyond the jupport it provided to the proc,ram% undertaken by industry. The additional F: & 0 widened Lonsidcrably the range of technols\$es available for commercialization. and considerabr: reduced costs. Without NASA’s support, fil-st sommercialization would probably have rmbodied AT & T’s [37] low altitude system invoiving large numbers of satellites. instead of the edormously cheaper synchronous satrliite alternative invoi.Jing only up to three satellites. Third, the fact tilzt NASA sponsored ~@cutions R 8 D after having arrived at the basic design solution to S.C. synchronous satellites. This is important for two reasons: first, there are indivisibiiities in this research, since it is most economical. to ur,dertake a very wide spectrum of applications eu:oeriments together in the context of a givec program than it is to perform a series of indivi.iual experiments ezch one suited to the needs of a particular customer; second, there are spin-offs (externalities) flowing from research primarily useful for some applications \A:hich benefit other applica-
mum pornr deal?n frlr a particular applic;ttictn. Thus. the accumulated data hail rc*prtt\znt\ .I hnowledge infrahtructurr riemcnt I($ tnr InJu\tr\. which should he diffferrntiatcd from t,mplhlc capital infrastruc,turr components. In S.C. ;I 4uhataratial accum~td;lti~~n 0i knot\ ledge ;icc~mp.~nicd the RELAY and SYNCOM Programs. The? enhanced the understanding of the (high energ!, part~clc) sp:ice environment and enabled the optimlzsiian of c’omrnuni~:atic~n and other suh~~~t~ws.
Prior to prool’ of fc..lhihilit> of a basic dwpn s’olution. expected pri\ate hencflts ma\ he lsw .knd risks high so expected private utiliti of R & I) ma>’ easily be negative. Expcctcd wc1a1 utilit!. ho\vever, may be po5itil.c due to rxtcrnalitic> and 1owl:r social risk: relative to pritate rihh% ;\fter ;I basic design solution is arri\.cd at. the pr!\.itt* profitability (colnmercial rihh) of ~ub~qur:nt R 8: D whose objective is IO optimiLc. ad;lpt aud improve such a design incc*eascs (drcr~a~~\) [3’J]. Under these cctnditions. ‘baseline tetchnolog~ * R 81:D should be: sp,.msorrd by the (~jovrrnnlcnt x.vhiKe subsequent R & D should be left to the private sector. The above reasoning tvould hat-e ied N.&S.-\ t1.l launch RELAI’ and once its fsasibiiit> \~a> Fr~~~~d tc improve upon it in conjunction u.ith the pri\.itc sector. But \vhy did NASA undertake the Sj’SCO&I Program which led to a more effecti\e basic design solution? -The anhwer lies in the gap cr~\at~d ht:twdzn the social and private expected uuht> once the synchronous satellite idea became available. Given that there already existed a psn~~ed basic design (RELAY-type active satellite s>>tcmx) and tha: the nen proposed design V.X \er\ rihh> for private firms, the latter would not ha\.~‘und~r-
ta\,cn the pr+~t. at least as early ;lj NASA did. !,oci;il utility of the proH
have made sense. L’.T the development r)f a even before !hc full non-synchronous 5.c.
role of Government sponsorerl R & D mav have to bt: enhanced duri:.g depressictns rather than being reduced. Finally. foreign Governments. continued support of certain technologies may justify. in certain cases. enhanced (and possibly redirected) public support at home. We do not know of any rigorous criteria for identifying these cases in practice.
u,i.s full\ nzalized. Fcticr;tI supp.)rt for S.C. technology mdy be juhtifiecl e\i’n hr$ond the stage of first commercialir;itit>n. for ;I ..ariety of reasons. Firht. yrlvate firma may have :I tendency to risk. incrcmcntal R & D only and ptzrfc>rm lc)i\ ni;~. nr@:ct longer term research on technologie3. even when these offer a positive social utilit?. In thc:4e c~t~c~. governments should step in. The currctlt con:,er\atism of the satellite communications coinmercial sector and potential for significant (if rishy) advailce is observed by P.L. Bargellini of COMSAT in presenting a table of potential imprcwmmts based on new technologies. He commelits: “Table 3. xvhich summarizes the situation re\~!als at least four arcas in which the new technc11.~~ has not been tried. Since some of the:,e tcchnoiogies appear quite promising, it is a;>proprla:i: to hope that the im3asse between iile rrquilements of operational systems and the !‘c’ed for cxpcriment will be broken. The soonr’r ihis il~paase is over$:ome the better; hotvevt r. tht bUC’ 3.5 of “coli\,rntional” Latellite systems dnd spacecraft design appear~s to have been partidIly responsiljle for slowing down exrerime*- .I programs. This situation is not surprisin since it has occurred many times in the past 7’ other fields of technology where large investments in oper;&or?ai systems retarded the introq>uctior of ..jsystems and components based on new technologies. notwithstanding the potenti;il promise. [40]. Second. the gap bt tween private and soci;ll C.XJeL?c(i utility (including the risk and benefit ap?r( priability factors) of developing new technolog es nlay comeivably increase during depressions. The ca.%h-flow problems of firms may deter them more than in normal times lrom undertaking R S: D. On &he other hand, the lapid introduction and diffusicn of new technologies may be critical to overcome the d=pre*;sion. On both counts the
NASA’s support of S.C. R & D had a m,.l,jor cffcct on thh: structure of the industry. and this i4 bscause of the variety of role:; it played within the innovation process. If NASA had simply subsidized part of the ongoing R & D efforts of industry then it is likely that the domination of AT & T on both domestic and international t*ommunications would have continued. This is because AT B T was the only private company which h,uJ already undertaken a considerable R & Ti effort of its own and was capable to proceed through commercialization of its non-synchronous system. i’he fact that NASA - beyond supporting TELST&R - undertook programs of its own such as RELAY and more important]} the successful SYNCOM Program (based on the Hughes idea of synchronous sa!ellites) opened up both the communications and the satellite and communications rquipment markets. Thus. transatlantic telcphclne via satellite turned out to be owned and operated by an international consortium - INTE.LSAT and the U.S. part by a private,‘public ccrporation with a relatively broad-based ownersh,p (COMSAT). Similarly. the technological preconditions were created for rhc FCC’s 1972 decis,on assuring multiple-entry into the U.S. domestic. S.C. market. (Finally. NASA contracting created hardware and system expertise in a wide variety of firms such as Hughes. RCA. etc.) The first commercial application or ’ ML” of S.C. was the transmission of telephone and TV sig.ials across the Atlantic. In the early 1960s this was the only possible commercial application given the high cost of the existing medium and low altitude satellite systems, e.g., based on AT & T’s TELSTAK. The existing supplier of telephone services in this market was AT & T (via underwater cnjtes) alld the eventual supplier was INTELSAT. AT 8.z T h;:ld a 29 percrnt share of COMSAT. the compa:ly
representing
the U.S. in that consortium.
tion to the suppliers ttzchnology’).
In addi-
of S.C. services (‘users
we have the ‘final
sides of the Atlantic
represented
u:,ers’
of the
on
by 3 vxiety
both of
government
agencies. From all this it is clear -that the issue of NASA’s relationship with the ‘users’ is a complex one. Some ‘ user’-related aspects which were important for the success in the transfer or commercialization of the technology include (I) Support of the R & D programs of existing suppliers of services (i.e.. of AT & T’s TELSTAR Program) without neglecting experimentation with other technolc,lgirs. (2) Increa! ing cooperation ::ith European countries to coordinate experimentation. This started with
ICHO and continued with RELAY. 1961 the telecommunication agencies of the J.K. and France agreed to build the ground stations for these P-.qrriments. This pattern of NASA Ional cooperation with the ‘final sponsored into, users’ of the f rst commercial system, enormously accelerated and faciljtated the establishment of INTELSAT. Moreover. the chain of ground sta(ions built was one of the foundations of the global system (see Smith [37]) and presumably explains the speed of the technology transfer process . . In
5. Concluding I marks The paper is an attempt at evaluating the COIItri,>ution ot’ NASA to the emcrgaence af the S.C. indc.lstry. It coinbines aspects of the quaiitati\,r ilistory of the technology and a partial quantitative Analysis of the costs and benefits of NAS.4.s invoi\.emcnt. Prior studies, to our knowledge. have generally emphasized one or the other, so it n1a) be useful to consider the advantages of combining both. Two specific features of the work include: ( 1) A distinction between base-line technology development a;ld subsequent technological devrlopment. The distinction is important because the qualitative case histories show that the contribution of NAS 4 is clear and direct in the former and indirect in the 1a:ter. Therefore, a partial and relatively standared cost-benefit analysis of NASA’s involvement appears as a possibility. Our present too!s of analysis do not permit us. how-
technoiogy transfer issue sinrze firm:, like siemens which first commercialized did not t)a>e their technology 011 contr:.icts with the Government but on their own R & D efforts. Finally. the user of the new technology in the West German case was a relatively clearly defined entity .- utilities or combinations of utilities and its role in choosing the technology to be used was paramount. In tleither case is this the situation with respect to : .c. P-&ably due to very special in~ti;utinnal and tecklnological characteristics of the industry. NASA acd other U.S. agencies played a much more active role both in arriving at the optimal baseline technology and in determining the particular nature ,Jf the technology user who ;vould own and operate the first system on a commercial scale. These characteristics may a1so limit the applicability of NASA’s experience to (:ther instances of Government sul;port of large tligh-technology projects. significant
[I21
N.
Rosenberg,
Inducemrnt
I131
The
Direction
Mrch::nisms
Rosenberg
(ed.).
Universilv
Press. Camhridge.
the course
amined
h.rveral flight
other
on an identification of
advanrage
(6) (Novrmher.
rrcchani?m.
I x11thi:,
parlance.
The u-phase
and
phase
in
the
phase.
S. Kuznrtr.
(San Fransisco
/~uz.
und Profits
Prop.ss National
Science
That
is, heyond
of an industry.
K Iznrts’s cycle
initi:ll
and
Technr logical
in: P. Kel y
rent I(mde&r
i nd
to
ap-
NSF’s
Innovation
M.
A Crrfr d
Kranzbcrg
Kearew
q
Cur-
P,-ess. 19’15 j; J. Enos, ,Perro-
(MIT
Prt ,s. Cambridge.
Found,ltion.
Washington.
Mass.,
Inrerucrron
in the Innoootion
Science Foundation.
[I61
A Eli 1 I
hstwcen the n-phase
mno\.tiion
Growth.
Scrence und Techndogv
References
fEEE
8: .~.:wrn.~
proc-ss
also to S
TL’L.~~o/c>~I
1962);
might
and Performance.
to Enos’a distinction
correspond\
Economic
(eds.)
We
is to NASA’s
and so is the hrst course. of ac~lon. Description
and the /?-phase of the innovatibjn
‘innovative’
In
centered
1975).
This corresponds
phcation
ex-
auto-
program.
rnech.!nisrn
Trunxuc~rrons on A erospwc~ trnd Elearon
[ISI
authors
issurs ;.nd the needed
the planning
Redisch. ATS-6
N.
or resolve these issues was the
suggest. to u,e economic comparative
tie
irlcluding
the SETI
of technological
operative
W.M.
and
of a planning
IO clarify
in:
IOX- 125. study
programs
control
experimentation focus
1976)
NASA
surface
Change:
Ue\lces.
O,I Te~hnoh~,:~, (Cambridge
of the present
each. the deve!opmcnt
(141
Focusing
Perspecrrces
During mated
of Technological
and
Ber~~ven
Prows
D.C..
(Na :ional
1973 j,
1970. the year when the TAT-5
cable uas
laid across :he Atlantic.
1171
The
data
‘l’ans
were obtained
of Goddard
expenditures pond
amounted
ECHO.
SYNCOM. and
experiments.
Tllr
not by NASA.
MRI
communications htes amounted Interview Center,
1191 1201
Alton
October
1978.
EC ,won,,c .\ , Krvue
t Novcmbcr.
C~unuclrennt~
‘f’tc~,,,rnn,ryuc~
I
I (4,
York.
[22]
1969) 570.-579.
Global [23]
TELSTAR
preceded
[24]
H.
An
Wood
Satellite
$29 and
of delay
spending
on
and G ciatelSpace
and
echo
(see section
rrdunda.ncy
on
Fucrhfres
in our
Flight the
I).
Policy. May
alternative and C.
.Srudr
197 I). c;il
of
in a sense we takt, the into
account
fit *as
Communications. Systems Conference, Decision,
6th
is $30.000.
Effect \eness
COMSAT
Corp.;
September
and Cables AIAA
hlontreal.
in
paper 1975.
in Intrrcon-
Communications Canada,
Cornmumcations
and the Problem
.ree B.
Cost
F. 26th Congress.
Role of Satellites
B. Owen. The lcternational TAT-6
figure
Reher,
Communications.
The
tinental
Rosen, July. 197X. to the general market,
include
paid by DOD
Goddard
of 1aunc.h failure
at the I.A.
Satellite
u\e and not a\allable
frequency
S. Ramji,
with Dr. H. Rosen. July, 1975. I hut was only in limited
of
costs although
presented
with Dr.H.
INTELSAT
SYNCOM
hasis. See Iniernutionul
however,
See [3]. p. 56.
[‘dl Inter\ll,w Interview
I ]‘)I [lrl
Jones
the effects
investment
Edelson.
1963).
the
and support%
zero).
IX1 H Ro\en. Synchronous C‘ommunrcat~on
about
exclude,
actual
as and
the costs of
to the ATS-F
of Telecommunications
\atellitr 171 1l.c‘. kludler and J.E. Tilron. Rrscarch .md De~elopmenr (‘oats as a Barrier to Entr). The C‘ut. udrtrn Journul (I/
prier
million.
to $137 million.
On a present-value We
of
presumably
those he-
distributed
$43.6
include
of voice communication>
(Office
I?]1
million.
reports that total NASA
satellites
with
Especially quality
costs
stations
proJected
(inc’.lding
RELAY.
Costs
Development
Total
launch vehicle. ground operations
million on ground
[‘Xl
to $130.7
million.
Project
Center.
programs
$19 million.
$68
:.pacecraft,
Ihe
Flight
on the three
1965)
follows:
from
Space
1976.
Industry.
of Regulated
th:
Uiligopoly
(Departmtxt July.
of Ec~~~~rnrc.s. St.lnf~~rd I:n!\t
rvt!.
reb 14
lY76).
[?S] If (i) doeh lwt hold then pari 01’ the direct WC ascribe
to the
p<,st-h.s.c.t.
~cchnc~logy.
[Zh] Over
and
demand [27] This
hrkond
the
effects
for telephone
is because
rather
h.a.c.1. \\oulil
circuits
really
CI~ the pra
we calculate
sa,ing:, cir,xith.
life for B new
design life hetaecn technology:
01
ela>tlclt~
111
rouie.
per ?I)-\ear
circuit
issue here is thr allocat~cw 1.11the rexcwrc’c’
savings from substituting design
vl~lcll
in the mam Atlantic
than savings per I-year
[2X] The theoretical
bcncfit\
he the rc\ult
an older trchnol<:g,
~echnolngq
wth
with ;I I~wg
;L re ativel!
two htagcs in the hibtor.
the !wccline
technclney
ah~~rt
01 the ncu
and the post-baseline
improvements. 1291 For
the definition
Ew7orm
Grcwrir
Cambridge. [30]
See T&le
of maJor of
tvla!~.
lY7l)
6. which
is taken
have hecome re!-cant
[32]
100 tears
major
innovatior~s.
for the full impact
[33)
For example. If satellite time).
a generation
meas
as the
It is not surprihin:.
to tha
tllc markrt lo;4
work.
cial communications
therefore.
on rezourcc1,
need. Benefits
should
such a netal
rhat we hate
nc, rc;ll
trchnol-
.stutl;~. Ior cxsmplc.
rccuwmic
stawn5
inlpact.
of C’0MISA.I
Thc\e
:
grw
arrived
and channel capdcitb ): ae
of firms augmented were subsequently markets
by th& applied
firms
intcrxtlt)li to commrr-
are also reavded.
However.
issues for ;I ~1s~. benefit
;lnJlx\l\
not yet been addwaed. at
WNCCM
the subsequent applications de\rloped
Inth ~,f
etc. Case !.tudie!. of jww trchn~)-
[36] This wab the case not only with respect to the xxic solution
from Job.
found
commumcatlon\
The MKI
.md revenues
the basic methodological have apparently
un:, ~tlhflcd nwd
This may be il \‘tx!I’ difficult
for haroware.
capabilities
with NASA
r.itc ~11
program
value of mee!lng
of direct
tb : bystem (ground
;L‘fall’
it Dale> not saw
ory ;b u major ib..wvation. invcslments
he rc-
1~1;I region fcv the t”lr\t
seriiccs
analcsilr of satellite
rcterb to mesure:
for
~)f current
two ma:, *till
a prevxwly
directly
society’s point (>f view
clude
applicatior~s w
t~rc\h
Even all~luing
in the b.s.c.t.
by definition
he csrimated
it:slf.
to bc felt in the cccxxwiy.
telephone
devoted
Add~tl<~~.~l
4tilger
as a result of the ATS
technology
then
cxt-hcnefil
[3] stud!.
should at least he artrihutrll
(e.g.. providing
I’rcr.
engine. few cuample.
in the various
tc~ its investment
previously
from
aam
quired
[34]
cr\lty
333.
to manifest
lead timts
For this NASA
me S. Ku/n~t\. Iin
since.
shorter
return
(iSI
pp. 314
The full impact of Walt’s more than
f Harvard
pal ential or at vmou~
apphcatlons. [3l]
innovation
h'trrrons
hut ail,,> ulth
K Sr 11 (4TS)
in the latter were :llso located
and had immediate
commerci.ll
dr~_rn
rqxct
ICI
The capahilirle*. 111011: con~ract~v implic,ltions.
It I\