-
61 guidance
beam(-climber, -follower, -rider,-riding) guidance — наведение (ракеты) по лучу
reference trajectory reentry guidance — управление КЛА при возвращении в атмосферу с использованием опорной траектории
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62 system
1) система; комплекс2) совокупность•- absolutely consistent system - absolutely direct indecomposable system - absolutely free system - absolutely irreducible system - absolutely isolated system - allowable coordinate system - almost linear system - ample linear system - artificial feel system - automatic block system - automatic deicing system - binary relational system - binary-coded decimal system - block tooling system - Cartesian coordinate system - completely controllable system - completely ergodic system - completely hyperbolic system - completely identifiable system - completely integrable system - completely irreducible system - completely regular system - completely stable system - completely stratified system - complex number system - conical coordinate system - derivational formal system - differential equation system - differential selsyn system - digital counting system - digital transmission system - elliptic coordinate system - elliptic cylindrical coordinate system - externally inconsistent system - finite state system - finitely axiomatizable system - finitely presented system - fully characteristic quotient system - fundamental system of solutions - hydraulic lift system - integrated switching system - isomorphically embedded system - kernel normal system - linearly dependent system - linearly independent system - live hydraulic system - locking protection system - meteor-burst communication system - modular programming system - parabolic cylindrical coordinate system - permanent four-wheel drive system - pure independent system - radio telephone system - reactor protection system - real number system - receiver-amplifier crioelectric system - remote-cylinder hydraulic system - semantically consistent system - simply consistent system - simply incomplete system - simply ordered system - spherical coordinate system - strongly multiplicative system - structurally stable system - sufficiently general coordinate system - system of frequency curves - system of rational numbers - time multiplex system - time-division multiplex system - uniformly complete system - univalent system of notation - universal system of notation - weakly closed system - weighted number system -
63 mode
2) мода, вид [форма, тип\] колебаний; вид [тип\] волн5) вчт. состояние6) швейн. мода•-
ablative pit-forming mode
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abnormal mode
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acceleration mode
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access mode
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accumulation mode
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acoustic mode
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acquisition mode
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active mode
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adaptive control mode
-
addressing mode
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air-liquefaction mode
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alternate mode
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anticipation mode
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approach mode
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assemble mode
-
astable vibration mode
-
astable mode
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automatic mode
-
automatic opening mode
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automatic skinning mode
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autopilot heading mode
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autoposition mode
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avalanche mode
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axial mode
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background mode
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backward mode
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backward propagating mode
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backward scattering mode
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backward scatter mode
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backward traveling mode
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bare resonator mode
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basic mode
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batch mode
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birefringent mode
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block mode
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block-multiplex mode
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bound modes
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broadcast mode
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buckling mode
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burst mode
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calibration mode
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capture mode
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cavity flipping mode
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cavity mode
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central mode
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character generation mode
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character mode
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characteristic mode
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charge-coupling mode
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circularly polarized mode
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cladding mode
-
clockwise polarized mode
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coherently locked modes
-
cold mode
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collective modes
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command mode
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common failure mode
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common mode
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compatibility mode
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competing modes
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compute mode
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confined mode
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constant cutting speed mode
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constant speed mode
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contention mode
-
continuous mode
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continuous path mode
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continuous-wave mode
-
contour modes
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contradirectional modes
-
control mode
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conversational mode
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cooling mode
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co-orbital mode
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coplanar mode
-
core-guided mode
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core mode
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counterclockwise polarized mode
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counterrotating circularly polarized modes
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counting mode
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coupled modes
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cross polarized modes
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cubic mode
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current mode
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current saving mode
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cutoff mode
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cutting mode
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damped mode
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data-processing mode
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Debye-like mode
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Debye mode
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deceleration mode
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deflected mode
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degenerated mode
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degenerate mode
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depletion mode
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design mode
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dialog mode
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difference mode
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differential mode
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diffraction-limited mode
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diffusive mode
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discrete mode
-
dispersion modes
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display mode
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distributed-feedback mode
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DNC mode
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dominant mode
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double-pass mode
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drift mode
-
dual-processing mode
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duplex mode
-
dynamic mode
-
dynamic-scattering mode
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E mode
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edge mode
-
edit mode
-
eigen mode
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electromagnetic mode
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elementary mode
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Emn mode
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emulation mode
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energy dissipating mode
-
enhancement mode
-
equal-loss modes
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equally spaced modes
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erase mode
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evanescent mode
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even mode
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excited mode
-
exciting mode
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executive mode
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extensional mode
-
extraordinary mode
-
Fabry-Perot mode
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face shear modes
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fast mode
-
faulted mode
-
fiber mode
-
filamentary mode
-
first mode
-
flexural mode
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forced mode
-
force mode
-
foreground mode
-
foreground-background mode
-
forward mode
-
forward propagating mode
-
forward scattering mode
-
forward scatter mode
-
forward shear mode
-
forward traveling mode
-
fracture mode
-
free-running mode
-
free-space mode
-
frequency-division multiplex mode
-
frequency-shift-keying mode
-
full program mode
-
full-duplex mode
-
fundamental mode
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gated mode
-
gate mode
-
Gaussian mode
-
generator mode
-
go-ahead mode
-
graphics mode
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graphic mode
-
guidance mode
-
guided-wave mode
-
guided mode
-
half-duplex mode
-
heating mode
-
height-lock mode
-
higher-order mode
-
high-frequency mode
-
high-loss mode
-
high-pass mode
-
high-resolution mode
-
Hmn mode
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horizontally polarized mode
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idler mode
-
independent mode
-
index mode
-
injected mode
-
injection-locked mode
-
in-phase modes
-
in-plane mode
-
insert mode
-
integer mode
-
interacting modes
-
interactive mode
-
internally trapped mode
-
interpretive mode
-
interrupt mode
-
inverter mode
-
isolated mode
-
jog mode
-
kernel mode
-
keyboard mode
-
laser mode
-
lasing mode
-
lattice mode
-
launched mode
-
leaking mode
-
leaky mode
-
left-hand polarized mode
-
left polarized mode
-
length extentional mode
-
length flexural mode
-
length modes
-
length-width flexural mode
-
light mode
-
linearly polarized mode
-
load mode
-
local mode
-
locate mode
-
lock mode
-
long coherence length mode
-
long wavelength mode
-
longitudinal mode
-
loopback mode
-
low-frequency mode
-
low-pass mode
-
low-resolution mode
-
lugdown mode
-
macro-by-macro mode
-
magnetron mode
-
main mode
-
malfunction mode
-
manual mode
-
manual skinning mode
-
mapping mode
-
maser mode
-
master mode
-
matched mode
-
measurement mode
-
message mode
-
mirror image mode
-
mixed mode
-
mode of behavior
-
mode of deformation
-
mode of excitation
-
mode of failure
-
mode of functioning
-
mode of propagation
-
mode of test
-
mode of transport
-
mode-locked mode
-
mode-match mode
-
monopulse mode
-
move mode
-
multiple-frame mode
-
multiplexed mode
-
multiplex mode
-
multitask mode
-
native mode
-
natural mode
-
nonaxial mode
-
noncounting mode
-
nondegenerate mode
-
nondegenerative mode
-
nonoscillating mode
-
nonpropagating mode
-
nonradiative mode
-
nonresonant mode
-
nonspiking mode
-
nontransparent mode
-
normal mode
-
odd mode
-
off mode
-
off-axis mode
-
off-design mode
-
off-line mode
-
off-normal mode
-
on-line mode
-
on-link mode
-
opening fracture mode
-
opening mode
-
operating mode
-
optical mode
-
ordinary mode
-
original mode
-
orthogonally polarized modes
-
oscillating mode
-
oscillation mode
-
oscillatory mode
-
out-of-plane mode
-
overtype mode
-
parallel mode
-
parametric mode
-
parasitic mode
-
partially suppressed mode
-
path following mode
-
path modifying mode
-
penetration mode
-
periodic mode
-
perturbed mode
-
photographing mode
-
photon-counting mode
-
pipelined mode
-
plane mode
-
plane polarized mode
-
plasma mode
-
plasma-guide mode
-
playback mode
-
point-to-point path mode
-
polarization mode
-
polarization-bistable mode
-
polarized mode
-
posttrigger mode
-
power-down mode
-
p-polarized mode
-
pretrigger mode
-
principal mode
-
priviledged mode
-
propagating mode
-
propagation mode
-
pulse counting mode
-
pulsed mode
-
pump mode
-
push-pull mode
-
Q-spoiled mode
-
Q-switched mode
-
quadrupole mode
-
quantum noise limited mode
-
radial mode
-
radially polarized mode
-
radiating mode
-
radiation mode
-
rail mode
-
ranging mode
-
ready mode
-
real-time mode
-
receive mode
-
record mode
-
rectifier mode
-
reflected mode
-
reflection mode
-
reflective mode
-
refracted mode
-
refrigeration mode
-
repetitive Q-switched mode
-
request mode
-
resonant mode
-
resonator mode
-
retropropulsion mode
-
return beam mode
-
reverse bias mode
-
reversible recording mode
-
right-hand polarized mode
-
right polarized mode
-
run mode
-
sample-and-hold mode
-
satellite mode
-
saturation mode
-
scanning mode
-
scan mode
-
scope mode
-
screen mode
-
search mode
-
selected mode
-
selector mode
-
self-ammoniation mode
-
self-heating mode
-
self-locked mode
-
self-Q-switched mode
-
self-refresh mode
-
self-reporting mode
-
self-trapping mode
-
serial mode
-
series mode
-
setup mode
-
severe wear mode
-
shear mode of crack initiation
-
shear mode
-
side mode
-
signal mode
-
simplex mode
-
simulation mode
-
single block mode
-
single mode
-
single Q-switched mode
-
single-channel mode
-
single-character mode
-
single-pulse mode
-
single-step mode
-
slave mode
-
slightly coupled modes
-
spatial mode
-
spectral mode
-
spiking mode
-
split-screen mode
-
s-polarized mode
-
spurious mode
-
spurious pulse mode
-
square mode
-
stable mode
-
standby mode
-
standing-wave mode
-
start-stop mode
-
static mode
-
stationary mode
-
steady state mode
-
stiffened mode
-
still-frame mode
-
storage mode
-
store-and-forward mode
-
stretching mode
-
stripped cladding modes
-
strong mode
-
strongly excited mode
-
substrate mode
-
superradiant mode
-
supervisor mode
-
switching mode
-
symmetric modes
-
synchronously pumped mode
-
tape auto mode
-
teaching mode
-
tearing mode
-
thickness-extensional modes
-
time compression mode
-
time mode
-
time-difference mode
-
time-shared mode
-
torsional modes
-
track-and-hold mode
-
tracking mode
-
transcribe mode
-
transfer mode
-
transformed mode
-
transient mode
-
transit mode
-
transit-time mode
-
transmission mode
-
transparent mode
-
transverse mode
-
TRAPATT mode
-
trapped mode
-
trapped plasma avalanche transit time mode
-
traveling-wave mode
-
triggering mode
-
trimming mode
-
truncated mode
-
tuning mode
-
tunneling mode
-
twist mode
-
two-level mode
-
unattended mode
-
uncoupled modes
-
undamped mode
-
unmanned mode
-
unperturbed mode
-
unstable mode
-
unstiffened mode
-
vertically polarized mode
-
vibration mode
-
vibration-free mode
-
virtual mode
-
voting mode
-
waiting mode
-
walk-off mode
-
warped mode
-
wave mode
-
wavefront watched modes
-
waveguide mode
-
wavy slip mode
-
wear mode
-
whispering modes
-
whistler mode
-
width modes
-
write mode
-
zero-order mode -
64 officer
офицер; должностное лицо; сотрудник; укомплектовывать офицерским составом; командоватьAir officer, Administration, Strike Command — Бр. начальник административного управления командования ВВС в Великобритании
Air officer, Engineering, Strike Command — Бр. начальник инженерно-технического управления командования ВВС в Великобритании
Air officer, Maintenance, RAF Support Command — Бр. начальник управления технического обслуживания командования тыла ВВС
Air officer, Training, RAF Support Command — начальник управления подготовки ЛС командования тыла ВВС
assistant G3 plans officer — помощник начальника оперативного отдела [отделения] по планированию
Flag officer, Germany — командующий ВМС ФРГ
Flag officer, Naval Air Command — Бр. командующий авиацией ВМС
Flag officer, Submarines — Бр. командующий подводными силами ВМС
float an officer (through personnel channels) — направлять личное дело офицера (в различные кадровые инстанции);
General officer Commanding, Royal Marines — Бр. командующий МП
General officer Commanding, the Artillery Division — командир артиллерийской дивизии (БРА)
landing zone (aircraft) control officer — офицер по управлению авиацией в районе десантирования (ВДВ)
officer, responsible for the exercise — офицер, ответственный за учение (ВМС)
Principal Medical officer, Strike Command — Бр. начальник медицинской службы командования ВВС в Великобритании
Senior Air Staff officer, Strike Command — Бр. НШ командования ВВС в Великобритании
senior officer, commando assault unit — Бр. командир штурмового отряда «коммандос»
senior officer, naval assault unit — Бр. командир военно-морского штурмового отряда
senior officer, naval build-up unit — Бр. командир военно-морского отряда наращивания сил десанта
senior officer, present — старший из присутствующих начальников
senior officer, Royal Artillery — Бр. старший начальник артиллерии
senior officer, Royal Engineers — Бр. старший начальник инженерных войск
short service term (commissioned) officer — Бр. офицер, призываемый на кратковременную службу; офицер, проходящий службу по краткосрочному контракту
tactical air officer (afloat) — офицер по управлению ТА поддержки (морского) десанта (на корабле управления)
The Dental officer, US Marine Corps — начальник зубоврачебной службы МП США
The Medical officer, US Marine Corps — начальник медицинской службы МП США
— burial supervising officer— company grade officer— education services officer— field services officer— fire prevention officer— general duty officer— information activities officer— logistics readiness officer— regular commissioned officer— security control officer— supply management officer— transportation officer— water supply officer* * * -
65 Artificial Intelligence
In my opinion, none of [these programs] does even remote justice to the complexity of human mental processes. Unlike men, "artificially intelligent" programs tend to be single minded, undistractable, and unemotional. (Neisser, 1967, p. 9)Future progress in [artificial intelligence] will depend on the development of both practical and theoretical knowledge.... As regards theoretical knowledge, some have sought a unified theory of artificial intelligence. My view is that artificial intelligence is (or soon will be) an engineering discipline since its primary goal is to build things. (Nilsson, 1971, pp. vii-viii)Most workers in AI [artificial intelligence] research and in related fields confess to a pronounced feeling of disappointment in what has been achieved in the last 25 years. Workers entered the field around 1950, and even around 1960, with high hopes that are very far from being realized in 1972. In no part of the field have the discoveries made so far produced the major impact that was then promised.... In the meantime, claims and predictions regarding the potential results of AI research had been publicized which went even farther than the expectations of the majority of workers in the field, whose embarrassments have been added to by the lamentable failure of such inflated predictions....When able and respected scientists write in letters to the present author that AI, the major goal of computing science, represents "another step in the general process of evolution"; that possibilities in the 1980s include an all-purpose intelligence on a human-scale knowledge base; that awe-inspiring possibilities suggest themselves based on machine intelligence exceeding human intelligence by the year 2000 [one has the right to be skeptical]. (Lighthill, 1972, p. 17)4) Just as Astronomy Succeeded Astrology, the Discovery of Intellectual Processes in Machines Should Lead to a Science, EventuallyJust as astronomy succeeded astrology, following Kepler's discovery of planetary regularities, the discoveries of these many principles in empirical explorations on intellectual processes in machines should lead to a science, eventually. (Minsky & Papert, 1973, p. 11)5) Problems in Machine Intelligence Arise Because Things Obvious to Any Person Are Not Represented in the ProgramMany problems arise in experiments on machine intelligence because things obvious to any person are not represented in any program. One can pull with a string, but one cannot push with one.... Simple facts like these caused serious problems when Charniak attempted to extend Bobrow's "Student" program to more realistic applications, and they have not been faced up to until now. (Minsky & Papert, 1973, p. 77)What do we mean by [a symbolic] "description"? We do not mean to suggest that our descriptions must be made of strings of ordinary language words (although they might be). The simplest kind of description is a structure in which some features of a situation are represented by single ("primitive") symbols, and relations between those features are represented by other symbols-or by other features of the way the description is put together. (Minsky & Papert, 1973, p. 11)[AI is] the use of computer programs and programming techniques to cast light on the principles of intelligence in general and human thought in particular. (Boden, 1977, p. 5)The word you look for and hardly ever see in the early AI literature is the word knowledge. They didn't believe you have to know anything, you could always rework it all.... In fact 1967 is the turning point in my mind when there was enough feeling that the old ideas of general principles had to go.... I came up with an argument for what I called the primacy of expertise, and at the time I called the other guys the generalists. (Moses, quoted in McCorduck, 1979, pp. 228-229)9) Artificial Intelligence Is Psychology in a Particularly Pure and Abstract FormThe basic idea of cognitive science is that intelligent beings are semantic engines-in other words, automatic formal systems with interpretations under which they consistently make sense. We can now see why this includes psychology and artificial intelligence on a more or less equal footing: people and intelligent computers (if and when there are any) turn out to be merely different manifestations of the same underlying phenomenon. Moreover, with universal hardware, any semantic engine can in principle be formally imitated by a computer if only the right program can be found. And that will guarantee semantic imitation as well, since (given the appropriate formal behavior) the semantics is "taking care of itself" anyway. Thus we also see why, from this perspective, artificial intelligence can be regarded as psychology in a particularly pure and abstract form. The same fundamental structures are under investigation, but in AI, all the relevant parameters are under direct experimental control (in the programming), without any messy physiology or ethics to get in the way. (Haugeland, 1981b, p. 31)There are many different kinds of reasoning one might imagine:Formal reasoning involves the syntactic manipulation of data structures to deduce new ones following prespecified rules of inference. Mathematical logic is the archetypical formal representation. Procedural reasoning uses simulation to answer questions and solve problems. When we use a program to answer What is the sum of 3 and 4? it uses, or "runs," a procedural model of arithmetic. Reasoning by analogy seems to be a very natural mode of thought for humans but, so far, difficult to accomplish in AI programs. The idea is that when you ask the question Can robins fly? the system might reason that "robins are like sparrows, and I know that sparrows can fly, so robins probably can fly."Generalization and abstraction are also natural reasoning process for humans that are difficult to pin down well enough to implement in a program. If one knows that Robins have wings, that Sparrows have wings, and that Blue jays have wings, eventually one will believe that All birds have wings. This capability may be at the core of most human learning, but it has not yet become a useful technique in AI.... Meta- level reasoning is demonstrated by the way one answers the question What is Paul Newman's telephone number? You might reason that "if I knew Paul Newman's number, I would know that I knew it, because it is a notable fact." This involves using "knowledge about what you know," in particular, about the extent of your knowledge and about the importance of certain facts. Recent research in psychology and AI indicates that meta-level reasoning may play a central role in human cognitive processing. (Barr & Feigenbaum, 1981, pp. 146-147)Suffice it to say that programs already exist that can do things-or, at the very least, appear to be beginning to do things-which ill-informed critics have asserted a priori to be impossible. Examples include: perceiving in a holistic as opposed to an atomistic way; using language creatively; translating sensibly from one language to another by way of a language-neutral semantic representation; planning acts in a broad and sketchy fashion, the details being decided only in execution; distinguishing between different species of emotional reaction according to the psychological context of the subject. (Boden, 1981, p. 33)Can the synthesis of Man and Machine ever be stable, or will the purely organic component become such a hindrance that it has to be discarded? If this eventually happens-and I have... good reasons for thinking that it must-we have nothing to regret and certainly nothing to fear. (Clarke, 1984, p. 243)The thesis of GOFAI... is not that the processes underlying intelligence can be described symbolically... but that they are symbolic. (Haugeland, 1985, p. 113)14) Artificial Intelligence Provides a Useful Approach to Psychological and Psychiatric Theory FormationIt is all very well formulating psychological and psychiatric theories verbally but, when using natural language (even technical jargon), it is difficult to recognise when a theory is complete; oversights are all too easily made, gaps too readily left. This is a point which is generally recognised to be true and it is for precisely this reason that the behavioural sciences attempt to follow the natural sciences in using "classical" mathematics as a more rigorous descriptive language. However, it is an unfortunate fact that, with a few notable exceptions, there has been a marked lack of success in this application. It is my belief that a different approach-a different mathematics-is needed, and that AI provides just this approach. (Hand, quoted in Hand, 1985, pp. 6-7)We might distinguish among four kinds of AI.Research of this kind involves building and programming computers to perform tasks which, to paraphrase Marvin Minsky, would require intelligence if they were done by us. Researchers in nonpsychological AI make no claims whatsoever about the psychological realism of their programs or the devices they build, that is, about whether or not computers perform tasks as humans do.Research here is guided by the view that the computer is a useful tool in the study of mind. In particular, we can write computer programs or build devices that simulate alleged psychological processes in humans and then test our predictions about how the alleged processes work. We can weave these programs and devices together with other programs and devices that simulate different alleged mental processes and thereby test the degree to which the AI system as a whole simulates human mentality. According to weak psychological AI, working with computer models is a way of refining and testing hypotheses about processes that are allegedly realized in human minds.... According to this view, our minds are computers and therefore can be duplicated by other computers. Sherry Turkle writes that the "real ambition is of mythic proportions, making a general purpose intelligence, a mind." (Turkle, 1984, p. 240) The authors of a major text announce that "the ultimate goal of AI research is to build a person or, more humbly, an animal." (Charniak & McDermott, 1985, p. 7)Research in this field, like strong psychological AI, takes seriously the functionalist view that mentality can be realized in many different types of physical devices. Suprapsychological AI, however, accuses strong psychological AI of being chauvinisticof being only interested in human intelligence! Suprapsychological AI claims to be interested in all the conceivable ways intelligence can be realized. (Flanagan, 1991, pp. 241-242)16) Determination of Relevance of Rules in Particular ContextsEven if the [rules] were stored in a context-free form the computer still couldn't use them. To do that the computer requires rules enabling it to draw on just those [ rules] which are relevant in each particular context. Determination of relevance will have to be based on further facts and rules, but the question will again arise as to which facts and rules are relevant for making each particular determination. One could always invoke further facts and rules to answer this question, but of course these must be only the relevant ones. And so it goes. It seems that AI workers will never be able to get started here unless they can settle the problem of relevance beforehand by cataloguing types of context and listing just those facts which are relevant in each. (Dreyfus & Dreyfus, 1986, p. 80)Perhaps the single most important idea to artificial intelligence is that there is no fundamental difference between form and content, that meaning can be captured in a set of symbols such as a semantic net. (G. Johnson, 1986, p. 250)Artificial intelligence is based on the assumption that the mind can be described as some kind of formal system manipulating symbols that stand for things in the world. Thus it doesn't matter what the brain is made of, or what it uses for tokens in the great game of thinking. Using an equivalent set of tokens and rules, we can do thinking with a digital computer, just as we can play chess using cups, salt and pepper shakers, knives, forks, and spoons. Using the right software, one system (the mind) can be mapped into the other (the computer). (G. Johnson, 1986, p. 250)19) A Statement of the Primary and Secondary Purposes of Artificial IntelligenceThe primary goal of Artificial Intelligence is to make machines smarter.The secondary goals of Artificial Intelligence are to understand what intelligence is (the Nobel laureate purpose) and to make machines more useful (the entrepreneurial purpose). (Winston, 1987, p. 1)The theoretical ideas of older branches of engineering are captured in the language of mathematics. We contend that mathematical logic provides the basis for theory in AI. Although many computer scientists already count logic as fundamental to computer science in general, we put forward an even stronger form of the logic-is-important argument....AI deals mainly with the problem of representing and using declarative (as opposed to procedural) knowledge. Declarative knowledge is the kind that is expressed as sentences, and AI needs a language in which to state these sentences. Because the languages in which this knowledge usually is originally captured (natural languages such as English) are not suitable for computer representations, some other language with the appropriate properties must be used. It turns out, we think, that the appropriate properties include at least those that have been uppermost in the minds of logicians in their development of logical languages such as the predicate calculus. Thus, we think that any language for expressing knowledge in AI systems must be at least as expressive as the first-order predicate calculus. (Genesereth & Nilsson, 1987, p. viii)21) Perceptual Structures Can Be Represented as Lists of Elementary PropositionsIn artificial intelligence studies, perceptual structures are represented as assemblages of description lists, the elementary components of which are propositions asserting that certain relations hold among elements. (Chase & Simon, 1988, p. 490)Artificial intelligence (AI) is sometimes defined as the study of how to build and/or program computers to enable them to do the sorts of things that minds can do. Some of these things are commonly regarded as requiring intelligence: offering a medical diagnosis and/or prescription, giving legal or scientific advice, proving theorems in logic or mathematics. Others are not, because they can be done by all normal adults irrespective of educational background (and sometimes by non-human animals too), and typically involve no conscious control: seeing things in sunlight and shadows, finding a path through cluttered terrain, fitting pegs into holes, speaking one's own native tongue, and using one's common sense. Because it covers AI research dealing with both these classes of mental capacity, this definition is preferable to one describing AI as making computers do "things that would require intelligence if done by people." However, it presupposes that computers could do what minds can do, that they might really diagnose, advise, infer, and understand. One could avoid this problematic assumption (and also side-step questions about whether computers do things in the same way as we do) by defining AI instead as "the development of computers whose observable performance has features which in humans we would attribute to mental processes." This bland characterization would be acceptable to some AI workers, especially amongst those focusing on the production of technological tools for commercial purposes. But many others would favour a more controversial definition, seeing AI as the science of intelligence in general-or, more accurately, as the intellectual core of cognitive science. As such, its goal is to provide a systematic theory that can explain (and perhaps enable us to replicate) both the general categories of intentionality and the diverse psychological capacities grounded in them. (Boden, 1990b, pp. 1-2)Because the ability to store data somewhat corresponds to what we call memory in human beings, and because the ability to follow logical procedures somewhat corresponds to what we call reasoning in human beings, many members of the cult have concluded that what computers do somewhat corresponds to what we call thinking. It is no great difficulty to persuade the general public of that conclusion since computers process data very fast in small spaces well below the level of visibility; they do not look like other machines when they are at work. They seem to be running along as smoothly and silently as the brain does when it remembers and reasons and thinks. On the other hand, those who design and build computers know exactly how the machines are working down in the hidden depths of their semiconductors. Computers can be taken apart, scrutinized, and put back together. Their activities can be tracked, analyzed, measured, and thus clearly understood-which is far from possible with the brain. This gives rise to the tempting assumption on the part of the builders and designers that computers can tell us something about brains, indeed, that the computer can serve as a model of the mind, which then comes to be seen as some manner of information processing machine, and possibly not as good at the job as the machine. (Roszak, 1994, pp. xiv-xv)The inner workings of the human mind are far more intricate than the most complicated systems of modern technology. Researchers in the field of artificial intelligence have been attempting to develop programs that will enable computers to display intelligent behavior. Although this field has been an active one for more than thirty-five years and has had many notable successes, AI researchers still do not know how to create a program that matches human intelligence. No existing program can recall facts, solve problems, reason, learn, and process language with human facility. This lack of success has occurred not because computers are inferior to human brains but rather because we do not yet know in sufficient detail how intelligence is organized in the brain. (Anderson, 1995, p. 2)Historical dictionary of quotations in cognitive science > Artificial Intelligence
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66 point
головной [тыльный] дозор; ориентир; пункт; балл— ammunition breakdown point— dismounting point— drop-off point— initial rallying point— mounting point— objective rallying point— starting point— strategic focal point -
67 SCAN
1) Общая лексика: Shipment Confirmation Acceptance Notice (2006, a new PC Postage feature lets online shippers, and their customers, know their packages have been picked up and are on their way. When mailers go online to ship packages, they can create PS Form 563), hum. сокр. Sequence Comparison ANalysis Program2) Военный термин: stock control and analysis, system for controlled approach of naval aircraft3) Психиатрия: Schedule for Clinical Assessment in Neuropsychiatry5) Юридический термин: State- Controlled Area Network, Suspected Child Abuse And Neglect6) Сокращение: Self-Correcting Automatic Navigator, Switch Communications Automatic Network (Army - genesis of AUTOVON), Switched-Circuit Automatic Network, antenna scan7) Университет: Student Community Action Network8) Деловая лексика: System For Convection Analysis And Nowcasting9) Сетевые технологии: switched circuit automatic network, автоматическая сеть с коммутируемыми каналами10) Контроль качества: schedule analysis11) Расширение файла: Supermarket Computer Answering Service -
68 Scan
1) Общая лексика: Shipment Confirmation Acceptance Notice (2006, a new PC Postage feature lets online shippers, and their customers, know their packages have been picked up and are on their way. When mailers go online to ship packages, they can create PS Form 563), hum. сокр. Sequence Comparison ANalysis Program2) Военный термин: stock control and analysis, system for controlled approach of naval aircraft3) Психиатрия: Schedule for Clinical Assessment in Neuropsychiatry5) Юридический термин: State- Controlled Area Network, Suspected Child Abuse And Neglect6) Сокращение: Self-Correcting Automatic Navigator, Switch Communications Automatic Network (Army - genesis of AUTOVON), Switched-Circuit Automatic Network, antenna scan7) Университет: Student Community Action Network8) Деловая лексика: System For Convection Analysis And Nowcasting9) Сетевые технологии: switched circuit automatic network, автоматическая сеть с коммутируемыми каналами10) Контроль качества: schedule analysis11) Расширение файла: Supermarket Computer Answering Service -
69 scan
1) Общая лексика: Shipment Confirmation Acceptance Notice (2006, a new PC Postage feature lets online shippers, and their customers, know their packages have been picked up and are on their way. When mailers go online to ship packages, they can create PS Form 563), hum. сокр. Sequence Comparison ANalysis Program2) Военный термин: stock control and analysis, system for controlled approach of naval aircraft3) Психиатрия: Schedule for Clinical Assessment in Neuropsychiatry5) Юридический термин: State- Controlled Area Network, Suspected Child Abuse And Neglect6) Сокращение: Self-Correcting Automatic Navigator, Switch Communications Automatic Network (Army - genesis of AUTOVON), Switched-Circuit Automatic Network, antenna scan7) Университет: Student Community Action Network8) Деловая лексика: System For Convection Analysis And Nowcasting9) Сетевые технологии: switched circuit automatic network, автоматическая сеть с коммутируемыми каналами10) Контроль качества: schedule analysis11) Расширение файла: Supermarket Computer Answering Service -
70 operation
работа, действие; операция; бой, сражение; основная функция; деятельность; оперирование, манипуляция; эксплуатация; управление, пилотирование (ЛА) ; pl. полётыoperation of landing flaps — выпуск или уборка посадочных закрылков [щитков]
smooth operation of the aircraft — плавное управление [пилотирование] ЛА
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71 flap
flap nзакрылокflappingбиениеair flapвоздушная заслонкаapproach with flaps downзаход на посадку с выпущенными закрылкамиasymmetrical flapsнесимметрично выпущенные закрылкиasymmetric flaps operationнесимметрическая работа закрылковaugmented internal blown flapзакрылок с дополнительным внутренним обдувомautomatic flap positioningавтоматическая установка закрылковblade flappingбиение лопастиblown flapзакрылок со сдувом пограничного слояbrake flapтормозной щитокcooling flapстворка системы охлажденияcowl flapстворка капотаcowl flap actuation assemblyблок управления створками капота двигателяdifferentially operated flapдифференциально управляемый закрылокdive flapтормозной щитокdouble-slotted flapдвухщелевой закрылокengine cowl flapстворка капота двигателяextended flapвыпущенный закрылокextension flapвыдвижной закрылокextension flap tracksрельсы выпуска закрылковexternal blown flapзакрылок с внешним обдувомfail to use flapsне выполнять требуемый выпуск закрылковflap actuating shaftвал трансмиссии привода механизма закрылковflap actuatorмеханизм выпускаflap approach positionположение закрылков при заходе на посадкуflap carriageкаретка закрылкаflap deflectorдефлектор закрылкаflap en-route positionполетное положение закрылковflap exhaust gateстворка закрылка для реактивной струиflap false sparпродольная стенка закрылкаflap interconnection rodтяга синхронизации закрылковflap landing positionпосадочное положение закрылковflapping angleугол взмахаflapping hingeгоризонтальный шарнирflapping motionмаховое движениеflapping movementмаховое движениеflapping stopограничитель взмаха(лопасти несущего винта) flap position indicatorуказатель положения закрылковflap retracted positionубранное положение закрылковflaps angleугол отклонения закрылковflaps asymmetric angleугол асимметричности закрылковflaps asymmetry warning systemсистема сигнализации рассогласования закрылковflaps bussingсинхронизация закрылковflaps disagreementнесинхронность отклонения закрылковflaps disagreement angleугол несинхронности закрылковflaps drive systemсистема привода закрылковflap settingустановка закрылка(на определенный угол) flaps interconnectionсинхронизация закрылковflaps interconnection cableтрос синхронизации закрылковflaps interconnection systemсистема синхронизации закрылковflaps landing settingустановка закрылков на посадочный уголflap slot strapзашивка закрылочной щелиflaps motionотклонение закрылковflaps position transmitterдатчик указателя положения закрылковflaps retractionуборка закрылковflaps speedскорость при выпуске закрылковflaps takeoff settingустановка закрылков на взлетный уголflap structural configurationконфигурация конструкции закрылкаflap takeoff positionвзлетное положение закрылковflap vaneстекатель закрылкаfull-span flapзакрылок по всему размахуinboard flapвнутренний закрылокjet flapструйный закрылокlanding flapпосадочный щитокleading edge flapотклоняемый носокleading edge flap systemсистема привода предкрылковmultiple flapсоставной закрылокoutboard flapвнешний закрылокpartial flap landingпосадка с частично выпущенными закрылкамиpartial flaps retractionчастичная уборка закрылковplace the flaps inустанавливать закрылкиplain flapплоский закрылокrate of flaps motionскорость отклонения закрылковrecovery flapщиток вывода из пикированияretracted flapубранный закрылокset the flaps atустанавливать закрылкиsingle-slotted flapоднощелевой закрылокslot flapщелевой закрылокsplit flapразрезной закрылокsuction flapзакрылок с отсосом пограничного слояsymmetric flap extensionсимметричный выпуск закрылковsymmetric flap operationсимметричная работа закрылковtripple-slotted flapтрехщелевой закрылокwind flaps control systemсистема управления закрылкамиwing flapзакрылокwing flap control systemсистема управления закрылкамиwing flaps error transmitterдатчик рассогласования закрылковzero flaps speedскорость при полностью убранных закрылках -
72 angle
1. n 2. a◊to read the drift angle — відлічувати [відраховувати] кут знесення
•- advance angle - aircraft impact angle - airflow angle - angle of approach - angle of approach light - angle of ascent - angle of attack - angle of attack of the wing - angle of azimuth - angle of bank - angle of climb - angle of coverage - angle of crab - angle of deflection - angle of descent - angle of deviation - angle of dip - angle of dive - angle of downwash - angle of drift - angle of elevation - angle of exit - angle of glide - angle of incidence - angle of indraft - angle of lag - angle of landing - angle of list - angle of pitch - angle of roll - angle of shock - angle of sight - angle of slope - angle of stall - angle of torsion - angle of turn - angle of upwash - angle of view - angle of visibility - angle of wing setting - angle of yaw - angles of coverage - anhedral angle - approach noise angle - aspect angle - attack angle - attitude angle - automatic advance angle - azimuth angle - bank angle - bank synchro error angle - beam spread angle - bearing angle - best climb angle - beyond stall angle - bistatic angle - blade angle - blade-entrance angle - blade-exit angle - blade flapping angle - boresight angle - burble angle - cockpit cutoff angle - collision angle - constant climb angle - contour angle - control surface angle - convergence angle - correction angle - course angle - critical angle - crossed-loop angle - cutin angle - datum angle - deflection angle - descent angle - desired track angle - dihedral angle - divergence angle - drift angle - dwell angle - elevation angle - entrance angle - error angle - first constant climb angle - fixer advance angle - flapping angle - flap angle - flaps asymmetric angle - flaps disagreement angle - flight path angle - full angle - glide angle - glide slope angle - gliding angle - gravity drop angle - Greenwich hour angle - guidance angle - heading angle - heeling angle - hour angle - ignition dwell angle - ILS glidepath angle - indicated ILS glidepath angle - initial track angle - inlet angle of attack - intake angle of attack - intercept glide path angle - jet angle - lateral angle - list angle - look angle - magnetic track angle - meridian convergence angle - microphone orientation angle - navigation light dihedral angle - nozzle angle - nozzle convergence angle - nozzle divergence angle - off-axis angle - off-boresight angle - orbital plane angle - path angle - perigon angle - pitch angle - prestalling angle - ray angle - reentering angle - reference angle - reference approach angle - rigging angle - right angle - roll angle - rotation angle - rotor coning angle - round angle - screening angle - search angle - sense angle - setting angle - sharp angle - shock wave angle - sideslip angle - squint angle - stalling angle - start angle - static ground angle - steering angle - stop angle - sweep angle - sweepback angle - sweepforward angle - take-off angle - take-off noise angle - timing angle - toe-in angle - track angle - turn lead angle - viewing angle - visual angle - wheel alignment angle - wheel steering angle - wind angle - wing setting angle - wing sweep angle - zero-lift angle -
73 remote maintenance
дистанционное техническое обслуживание
Техническое обслуживание объекта, проводимое под управлением персонала без его непосредственного присутствия.
[ОСТ 45.152-99 ]Параллельные тексты EN-RU из ABB Review. Перевод компании Интент
Service from afarДистанционный сервисABB’s Remote Service concept is revolutionizing the robotics industryРазработанная АББ концепция дистанционного обслуживания Remote Service революционизирует робототехникуABB robots are found in industrial applications everywhere – lifting, packing, grinding and welding, to name a few. Robust and tireless, they work around the clock and are critical to a company’s productivity. Thus, keeping these robots in top shape is essential – any failure can lead to serious output consequences. But what happens when a robot malfunctions?Роботы АББ используются во всех отраслях промышленности для перемещения грузов, упаковки, шлифовки, сварки – всего и не перечислить. Надежные и неутомимые работники, способные трудиться день и ночь, они представляют большую ценность для владельца. Поэтому очень важно поддерживать их в надлежащей состоянии, ведь любой отказ может иметь серьезные последствия. Но что делать, если робот все-таки сломался?ABB’s new Remote Service concept holds the answer: This approach enables a malfunctioning robot to alarm for help itself. An ABB service engineer then receives whole diagnostic information via wireless technology, analyzes the data on a Web site and responds with support in just minutes. This unique service is paying off for customers and ABB alike, and in the process is revolutionizing service thinking.Ответом на этот вопрос стала новая концепция Remote Service от АББ, согласно которой неисправный робот сам просит о помощи. C помощью беспроводной технологии специалист сервисной службы АББ получает всю необходимую диагностическую информацию, анализирует данные на web-сайте и через считанные минуты выдает рекомендации по устранению отказа. Эта уникальная возможность одинаково ценна как для заказчиков, так и для самой компании АББ. В перспективе она способна в корне изменить весь подход к организации технического обслуживания.Every minute of production downtime can have financially disastrous consequences for a company. Traditional reactive service is no longer sufficient since on-site service engineer visits also demand great amounts of time and money. Thus, companies not only require faster help from the service organization when needed but they also want to avoid disturbances in production.Каждая минута простоя производства может привести к губительным финансовым последствиям. Традиционная организация сервиса, предусматривающая ликвидацию возникающих неисправностей, становится все менее эффективной, поскольку вызов сервисного инженера на место эксплуатации робота сопряжен с большими затратами времени и денег. Предприятия требуют от сервисной организации не только более быстрого оказания помощи, но и предотвращения возможных сбоев производства.In 2006, ABB developed a new approach to better meet customer’s expectations: Using the latest technologies to reach the robots at customer sites around the world, ABB could support them remotely in just minutes, thereby reducing the need for site visits. Thus the new Remote Service concept was quickly brought to fruition and was launched in mid-2007. Statistics show that by using the system the majority of production stoppages can be avoided.В 2006 г. компания АББ разработала новый подход к удовлетворению ожиданий своих заказчиков. Использование современных технологий позволяет специалистам АББ получать информацию от роботов из любой точки мира и в считанные минуты оказывать помощь дистанционно, в результате чего сокращается количество выездов на место установки. Запущенная в середине 2007 г. концепция Remote Service быстро себя оправдала. Статистика показывает, что её применение позволило предотвратить большое число остановок производства.Reactive maintenance The hardware that makes ABB Remote Service possible consists of a communication unit, which has a function similar to that of an airplane’s so-called black box 1. This “service box” is connected to the robot’s control system and can read and transmit diagnostic information. The unit not only reads critical diagnostic information that enables immediate support in the event of a failure, but also makes it possible to monitor and analyze the robot’s condition, thereby proactively detecting the need for maintenance.Устранение возникающих неисправностей Аппаратное устройство, с помощью которого реализуется концепция Remote Service, представляет собой коммуникационный блок, работающий аналогично черному ящику самолета (рис. 1). Этот блок считывает диагностические данные из контроллера робота и передает их по каналу GSM. Считывается не только информация, необходимая для оказания немедленной помощи в случае отказа, но и сведения, позволяющие контролировать и анализировать состояние робота для прогнозирования неисправностей и планирования технического обслуживания.If the robot breaks down, the service box immediately stores the status of the robot, its historical data (as log files), and diagnostic parameters such as temperature and power supply. Equipped with a built-in modem and using the GSM network, the box transmits the data to a central server for analysis and presentation on a dedicated Web site. Alerts are automatically sent to the nearest of ABB’s 1,200 robot service engineers who then accesses the detailed data and error log to analyze the problem.При поломке робота сервисный блок немедленно сохраняет данные о его состоянии, сведения из рабочего журнала, а также значения диагностических параметров (температура и характеристики питания). Эти данные передаются встроенным GSM-модемом на центральный сервер для анализа и представления на соответствующем web-сайте. Аварийные сообщения автоматически пересылаются ближайшему к месту аварии одному из 1200 сервисных инженеров-робототехников АББ, который получает доступ к детальной информации и журналу аварий для анализа возникшей проблемы.A remotely based ABB engineer can then quickly identify the exact fault, offering rapid customer support. For problems that cannot be solved remotely, the service engineer can arrange for quick delivery of spare parts and visit the site to repair the robot. Even if the engineer must make a site visit, service is faster, more efficient and performed to a higher standard than otherwise possible.Специалист АББ может дистанционно идентифицировать отказ и оказать быструю помощь заказчику. Если неисправность не может быть устранена дистанционно, сервисный инженер организовывает доставку запасных частей и выезд ремонтной бригады. Даже если необходимо разрешение проблемы на месте, предшествующая дистанционная диагностика позволяет минимизировать объем работ и сократить время простоя.Remote Service enables engineers to “talk” to robots remotely and to utilize tools that enable smart, fast and automatic analysis. The system is based on a machine-to-machine (M2M) concept, which works automatically, requiring human input only for analysis and personalized customer recommendations. ABB was recognized for this innovative solution at the M2M United Conference in Chicago in 2008 Factbox.Remote Service позволяет инженерам «разговаривать» с роботами на расстоянии и предоставляет в их распоряжение интеллектуальные средства быстрого автоматизированного анализа. Система основана на основе технологии автоматической связи машины с машиной (M2M), где участие человека сводится к анализу данных и выдаче рекомендаций клиенту. В 2008 г. это инновационное решение от АББ получило приз на конференции M2M United Conference в Чикаго (см. вставку).Proactive maintenanceRemote Service also allows ABB engineers to monitor and detect potential problems in the robot system and opens up new possibilities for proactive maintenance.Прогнозирование неисправностейRemote Service позволяет инженерам АББ дистанционно контролировать состояние роботов и прогнозировать возможные неисправности, что открывает новые возможности по организации профилактического обслуживания.The service box regularly takes condition measurements. By monitoring key parameters over time, Remote Service can identify potential failures and when necessary notify both the end customer and the appropriate ABB engineer. The management and storage of full system backups is a very powerful service to help recover from critical situations caused, for example, by operator errors.Сервисный блок регулярно выполняет диагностические измерения. Непрерывно контролируя ключевые параметры, Remote Service может распознать потенциальные опасности и, при необходимости, оповещать владельца оборудования и соответствующего специалиста АББ. Резервирование данных для возможного отката является мощным средством, обеспечивающим восстановление системы в критических ситуациях, например, после ошибки оператора.The first Remote Service installation took place in the automotive industry in the United States and quickly proved its value. The motherboard in a robot cabinet overheated and the rise in temperature triggered an alarm via Remote Service. Because of the alarm, engineers were able to replace a faulty fan, preventing a costly production shutdown.Первая система Remote Service была установлена на автозаводе в США и очень скоро была оценена по достоинству. Она обнаружила перегрев материнской платы в шкафу управления роботом и передала сигнал о превышении допустимой температуры, благодаря чему инженеры смогли заменить неисправный вентилятор и предотвратить дорогостоящую остановку производства.MyRobot: 24-hour remote access
Having regular access to a robot’s condition data is also essential to achieving lean production. At any time, from any location, customers can verify their robots’ status and access maintenance information and performance reports simply by logging in to ABB’s MyRobot Web site. The service enables customers to easily compare performances, identify bottlenecks or developing issues, and initiate the mostСайт MyRobot: круглосуточный дистанционный доступДля того чтобы обеспечить бесперебойное производство, необходимо иметь регулярный доступ к информации о состоянии робота. Зайдя на соответствующую страницу сайта MyRobot компании АББ, заказчики получат все необходимые данные, включая сведения о техническом обслуживании и отчеты о производительности своего робота. Эта услуга позволяет легко сравнивать данные о производительности, обнаруживать возможные проблемы, а также оптимизировать планирование технического обслуживания и модернизации. С помощью MyRobot можно значительно увеличить выпуск продукции и уменьшить количество выбросов.Award-winning solutionIn June 2008, the innovative Remote Service solution won the Gold Value Chain award at the M2M United Conference in Chicago. The value chain award honors successful corporate adopters of M2M (machine–to-machine) technology and highlights the process of combining multiple technologies to deliver high-quality services to customers. ABB won in the categoryof Smart Services.Приз за удачное решениеВ июне 2008 г. инновационное решение Remote Service получило награду Gold Value Chain (Золотая цепь) на конференции M2M United Conference в Чикаго. «Золотая цепь» присуждается за успешное масштабное внедрение технологии M2M (машина – машина), а также за достижения в объединении различных технологий для предоставления высококачественных услуг заказчикам. АББ одержала победу в номинации «Интеллектуальный сервис».Case study: Tetley Tetley GB Ltd is the world’s second-largest manufacturer and distributor of tea. The company’s manufacturing and distribution business is spread across 40 countries and sells over 60 branded tea bags. Tetley’s UK tea production facility in Eaglescliffe, County Durham is the sole producer of Tetley tea bags 2.Пример применения: Tetley Компания TetleyGB Ltd является вторым по величине мировым производителем и поставщиком чая. Производственные и торговые филиалы компании имеются в 40 странах, а продукция распространяется под 60 торговыми марками. Чаеразвесочная фабрика в Иглсклифф, графство Дарем, Великобритания – единственный производитель чая Tetley в пакетиках (рис. 2).ABB offers a flexible choice of service agreements for both new and existing robot installations, which can help extend the mean time between failures, shorten the time to repair and lower the cost of automated production.Предлагаемые АББ контракты на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и общую стоимость автоматизированного производства.Robots in the plant’s production line were tripping alarms and delaying the whole production cycle. The spurious alarms resulted in much unnecessary downtime that was spent resetting the robots in the hope that another breakdown could be avoided. Each time an alarm was tripped, several hours of production time was lost. “It was for this reason that we were keen to try out ABB’s Remote Service agreement,” said Colin Trevor, plant maintenance manager.Установленные в технологической линии роботы выдавали аварийные сигналы, задерживающие выполнение производственного цикла. Ложные срабатывания вынуждали перезапускать роботов в надежде предотвратить возможные отказы, в результате чего после каждого аварийного сигнала производство останавливалось на несколько часов. «Именно поэтому мы решили попробовать заключить с АББ контракт на дистанционное техническое обслуживание», – сказал Колин Тревор, начальник технической службы фабрики.To prevent future disruptions caused by unplanned downtime, Tetley signed an ABB Response Package service agreement, which included installing a service box and system infrastructure into the robot control systems. Using the Remote Service solution, ABB remotely monitors and collects data on the “wear and tear” and productivity of the robotic cells; this data is then shared with the customer and contributes to smooth-running production cycles.Для предотвращения ущерба в результате незапланированных простоев Tetley заключила с АББ контракт на комплексное обслуживание Response Package, согласно которому системы управления роботами были дооборудованы сервисными блоками с необходимой инфраструктурой. С помощью Remote Service компания АББ дистанционно собирает данные о наработке, износе и производительности роботизированных модулей. Эти данные предоставляются заказчику для оптимизации загрузки производственного оборудования.Higher production uptimeSince the implementation of Remote Service, Tetley has enjoyed greatly reduced robot downtime, with no further disruptions caused by unforeseen problems. “The Remote Service package has dramatically changed the plant,” said Trevor. “We no longer have breakdown issues throughout the shift, helping us to achieve much longer periods of robot uptime. As we have learned, world-class manufacturing facilities need world-class support packages. Remote monitoring of our robots helps us to maintain machine uptime, prevent costly downtime and ensures my employees can be put to more valuable use.”Увеличение полезного времениС момента внедрения Remote Service компания Tetley была приятно удивлена резким сокращением простоя роботов и отсутствием незапланированных остановок производства. «Пакет Remote Service резко изменил ситуацию на предприятии», – сказал Тревор. «Мы избавились от простоев роботов и смогли резко увеличить их эксплуатационную готовность. Мы поняли, что для производственного оборудования мирового класса необходим сервисный пакет мирового класса. Дистанционный контроль роботов помогает нам поддерживать их в рабочем состоянии, предотвращать дорогостоящие простои и задействовать наш персонал для выполнения более важных задач».Service accessRemote Service is available worldwide, connecting more than 500 robots. Companies that have up to 30 robots are often good candidates for the Remote Service offering, as they usually have neither the engineers nor the requisite skills to deal with robotics faults themselves. Larger companies are also enthusiastic about Remote Service, as the proactive services will improve the lifetime of their equipment and increase overall production uptime.Доступность сервисаСеть Remote Service охватывает более 700 роботов по всему миру. Потенциальными заказчиками Remote Service являются компании, имеющие до 30 роботов, но не имеющие инженеров и техников, способных самостоятельно устранять их неисправности. Интерес к Remote Service проявляют и более крупные компании, поскольку они заинтересованы в увеличении срока службы и эксплуатационной готовности производственного оборудования.In today’s competitive environment, business profitability often relies on demanding production schedules that do not always leave time for exhaustive or repeated equipment health checks. ABB’s Remote Service agreements are designed to monitor its customers’ robots to identify when problems are likely to occur and ensure that help is dispatched before the problem can escalate. In over 60 percent of ABB’s service calls, its robots can be brought back online remotely, without further intervention.В условиях современной конкуренции окупаемость бизнеса часто зависит от соблюдения жестких графиков производства, не оставляющих времени для полномасштабных или периодических проверок исправности оборудования. Контракт Remote Service предусматривает мониторинг состояния роботов заказчика для прогнозирования возможных неисправностей и принятие мер по их предотвращению. В более чем 60 % случаев для устранения неисправности достаточно дистанционной консультации в сервисной службе АББ, дальнейшего вмешательства не требуется.ABB offers a flexible choice of service agreements for both new and existing robot installations, which helps extend the mean time between failures, shorten the time to repair and lower the total cost of ownership. With four new packages available – Support, Response, Maintenance and Warranty, each backed up by ABB’s Remote Service technology – businesses can minimize the impact of unplanned downtime and achieve improved production-line efficiency.Компания АББ предлагает гибкий выбор контрактов на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, которые позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и эксплуатационные расходы. Четыре новых пакета на основе технологии Remote Service – Support, Response, Maintenance и Warranty – позволяют минимизировать внеплановые простои и значительно повысить эффективность производства.The benefits of Remote Sevice are clear: improved availability, fewer service visits, lower maintenance costs and maximized total cost of ownership. This unique service sets ABB apart from its competitors and is the beginning of a revolution in service thinking. It provides ABB with a great opportunity to improve customer access to its expertise and develop more advanced services worldwide.Преимущества дистанционного технического обслуживания очевидны: повышенная надежность, уменьшение выездов ремонтных бригад, уменьшение затрат на обслуживание и общих эксплуатационных расходов. Эта уникальная услуга дает компании АББ преимущества над конкурентами и демонстрирует революционный подход к организации сервиса. Благодаря ей компания АББ расширяет доступ заказчиков к опыту своих специалистов и получает возможность более эффективного оказания технической помощи по всему миру.Тематики
- тех. обсл. и ремонт средств электросвязи
Обобщающие термины
EN
Англо-русский словарь нормативно-технической терминологии > remote maintenance
74 remote sevice
дистанционное техническое обслуживание
Техническое обслуживание объекта, проводимое под управлением персонала без его непосредственного присутствия.
[ОСТ 45.152-99 ]Параллельные тексты EN-RU из ABB Review. Перевод компании Интент
Service from afarДистанционный сервисABB’s Remote Service concept is revolutionizing the robotics industryРазработанная АББ концепция дистанционного обслуживания Remote Service революционизирует робототехникуABB robots are found in industrial applications everywhere – lifting, packing, grinding and welding, to name a few. Robust and tireless, they work around the clock and are critical to a company’s productivity. Thus, keeping these robots in top shape is essential – any failure can lead to serious output consequences. But what happens when a robot malfunctions?Роботы АББ используются во всех отраслях промышленности для перемещения грузов, упаковки, шлифовки, сварки – всего и не перечислить. Надежные и неутомимые работники, способные трудиться день и ночь, они представляют большую ценность для владельца. Поэтому очень важно поддерживать их в надлежащей состоянии, ведь любой отказ может иметь серьезные последствия. Но что делать, если робот все-таки сломался?ABB’s new Remote Service concept holds the answer: This approach enables a malfunctioning robot to alarm for help itself. An ABB service engineer then receives whole diagnostic information via wireless technology, analyzes the data on a Web site and responds with support in just minutes. This unique service is paying off for customers and ABB alike, and in the process is revolutionizing service thinking.Ответом на этот вопрос стала новая концепция Remote Service от АББ, согласно которой неисправный робот сам просит о помощи. C помощью беспроводной технологии специалист сервисной службы АББ получает всю необходимую диагностическую информацию, анализирует данные на web-сайте и через считанные минуты выдает рекомендации по устранению отказа. Эта уникальная возможность одинаково ценна как для заказчиков, так и для самой компании АББ. В перспективе она способна в корне изменить весь подход к организации технического обслуживания.Every minute of production downtime can have financially disastrous consequences for a company. Traditional reactive service is no longer sufficient since on-site service engineer visits also demand great amounts of time and money. Thus, companies not only require faster help from the service organization when needed but they also want to avoid disturbances in production.Каждая минута простоя производства может привести к губительным финансовым последствиям. Традиционная организация сервиса, предусматривающая ликвидацию возникающих неисправностей, становится все менее эффективной, поскольку вызов сервисного инженера на место эксплуатации робота сопряжен с большими затратами времени и денег. Предприятия требуют от сервисной организации не только более быстрого оказания помощи, но и предотвращения возможных сбоев производства.In 2006, ABB developed a new approach to better meet customer’s expectations: Using the latest technologies to reach the robots at customer sites around the world, ABB could support them remotely in just minutes, thereby reducing the need for site visits. Thus the new Remote Service concept was quickly brought to fruition and was launched in mid-2007. Statistics show that by using the system the majority of production stoppages can be avoided.В 2006 г. компания АББ разработала новый подход к удовлетворению ожиданий своих заказчиков. Использование современных технологий позволяет специалистам АББ получать информацию от роботов из любой точки мира и в считанные минуты оказывать помощь дистанционно, в результате чего сокращается количество выездов на место установки. Запущенная в середине 2007 г. концепция Remote Service быстро себя оправдала. Статистика показывает, что её применение позволило предотвратить большое число остановок производства.Reactive maintenance The hardware that makes ABB Remote Service possible consists of a communication unit, which has a function similar to that of an airplane’s so-called black box 1. This “service box” is connected to the robot’s control system and can read and transmit diagnostic information. The unit not only reads critical diagnostic information that enables immediate support in the event of a failure, but also makes it possible to monitor and analyze the robot’s condition, thereby proactively detecting the need for maintenance.Устранение возникающих неисправностей Аппаратное устройство, с помощью которого реализуется концепция Remote Service, представляет собой коммуникационный блок, работающий аналогично черному ящику самолета (рис. 1). Этот блок считывает диагностические данные из контроллера робота и передает их по каналу GSM. Считывается не только информация, необходимая для оказания немедленной помощи в случае отказа, но и сведения, позволяющие контролировать и анализировать состояние робота для прогнозирования неисправностей и планирования технического обслуживания.If the robot breaks down, the service box immediately stores the status of the robot, its historical data (as log files), and diagnostic parameters such as temperature and power supply. Equipped with a built-in modem and using the GSM network, the box transmits the data to a central server for analysis and presentation on a dedicated Web site. Alerts are automatically sent to the nearest of ABB’s 1,200 robot service engineers who then accesses the detailed data and error log to analyze the problem.При поломке робота сервисный блок немедленно сохраняет данные о его состоянии, сведения из рабочего журнала, а также значения диагностических параметров (температура и характеристики питания). Эти данные передаются встроенным GSM-модемом на центральный сервер для анализа и представления на соответствующем web-сайте. Аварийные сообщения автоматически пересылаются ближайшему к месту аварии одному из 1200 сервисных инженеров-робототехников АББ, который получает доступ к детальной информации и журналу аварий для анализа возникшей проблемы.A remotely based ABB engineer can then quickly identify the exact fault, offering rapid customer support. For problems that cannot be solved remotely, the service engineer can arrange for quick delivery of spare parts and visit the site to repair the robot. Even if the engineer must make a site visit, service is faster, more efficient and performed to a higher standard than otherwise possible.Специалист АББ может дистанционно идентифицировать отказ и оказать быструю помощь заказчику. Если неисправность не может быть устранена дистанционно, сервисный инженер организовывает доставку запасных частей и выезд ремонтной бригады. Даже если необходимо разрешение проблемы на месте, предшествующая дистанционная диагностика позволяет минимизировать объем работ и сократить время простоя.Remote Service enables engineers to “talk” to robots remotely and to utilize tools that enable smart, fast and automatic analysis. The system is based on a machine-to-machine (M2M) concept, which works automatically, requiring human input only for analysis and personalized customer recommendations. ABB was recognized for this innovative solution at the M2M United Conference in Chicago in 2008 Factbox.Remote Service позволяет инженерам «разговаривать» с роботами на расстоянии и предоставляет в их распоряжение интеллектуальные средства быстрого автоматизированного анализа. Система основана на основе технологии автоматической связи машины с машиной (M2M), где участие человека сводится к анализу данных и выдаче рекомендаций клиенту. В 2008 г. это инновационное решение от АББ получило приз на конференции M2M United Conference в Чикаго (см. вставку).Proactive maintenanceRemote Service also allows ABB engineers to monitor and detect potential problems in the robot system and opens up new possibilities for proactive maintenance.Прогнозирование неисправностейRemote Service позволяет инженерам АББ дистанционно контролировать состояние роботов и прогнозировать возможные неисправности, что открывает новые возможности по организации профилактического обслуживания.The service box regularly takes condition measurements. By monitoring key parameters over time, Remote Service can identify potential failures and when necessary notify both the end customer and the appropriate ABB engineer. The management and storage of full system backups is a very powerful service to help recover from critical situations caused, for example, by operator errors.Сервисный блок регулярно выполняет диагностические измерения. Непрерывно контролируя ключевые параметры, Remote Service может распознать потенциальные опасности и, при необходимости, оповещать владельца оборудования и соответствующего специалиста АББ. Резервирование данных для возможного отката является мощным средством, обеспечивающим восстановление системы в критических ситуациях, например, после ошибки оператора.The first Remote Service installation took place in the automotive industry in the United States and quickly proved its value. The motherboard in a robot cabinet overheated and the rise in temperature triggered an alarm via Remote Service. Because of the alarm, engineers were able to replace a faulty fan, preventing a costly production shutdown.Первая система Remote Service была установлена на автозаводе в США и очень скоро была оценена по достоинству. Она обнаружила перегрев материнской платы в шкафу управления роботом и передала сигнал о превышении допустимой температуры, благодаря чему инженеры смогли заменить неисправный вентилятор и предотвратить дорогостоящую остановку производства.MyRobot: 24-hour remote access
Having regular access to a robot’s condition data is also essential to achieving lean production. At any time, from any location, customers can verify their robots’ status and access maintenance information and performance reports simply by logging in to ABB’s MyRobot Web site. The service enables customers to easily compare performances, identify bottlenecks or developing issues, and initiate the mostСайт MyRobot: круглосуточный дистанционный доступДля того чтобы обеспечить бесперебойное производство, необходимо иметь регулярный доступ к информации о состоянии робота. Зайдя на соответствующую страницу сайта MyRobot компании АББ, заказчики получат все необходимые данные, включая сведения о техническом обслуживании и отчеты о производительности своего робота. Эта услуга позволяет легко сравнивать данные о производительности, обнаруживать возможные проблемы, а также оптимизировать планирование технического обслуживания и модернизации. С помощью MyRobot можно значительно увеличить выпуск продукции и уменьшить количество выбросов.Award-winning solutionIn June 2008, the innovative Remote Service solution won the Gold Value Chain award at the M2M United Conference in Chicago. The value chain award honors successful corporate adopters of M2M (machine–to-machine) technology and highlights the process of combining multiple technologies to deliver high-quality services to customers. ABB won in the categoryof Smart Services.Приз за удачное решениеВ июне 2008 г. инновационное решение Remote Service получило награду Gold Value Chain (Золотая цепь) на конференции M2M United Conference в Чикаго. «Золотая цепь» присуждается за успешное масштабное внедрение технологии M2M (машина – машина), а также за достижения в объединении различных технологий для предоставления высококачественных услуг заказчикам. АББ одержала победу в номинации «Интеллектуальный сервис».Case study: Tetley Tetley GB Ltd is the world’s second-largest manufacturer and distributor of tea. The company’s manufacturing and distribution business is spread across 40 countries and sells over 60 branded tea bags. Tetley’s UK tea production facility in Eaglescliffe, County Durham is the sole producer of Tetley tea bags 2.Пример применения: Tetley Компания TetleyGB Ltd является вторым по величине мировым производителем и поставщиком чая. Производственные и торговые филиалы компании имеются в 40 странах, а продукция распространяется под 60 торговыми марками. Чаеразвесочная фабрика в Иглсклифф, графство Дарем, Великобритания – единственный производитель чая Tetley в пакетиках (рис. 2).ABB offers a flexible choice of service agreements for both new and existing robot installations, which can help extend the mean time between failures, shorten the time to repair and lower the cost of automated production.Предлагаемые АББ контракты на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и общую стоимость автоматизированного производства.Robots in the plant’s production line were tripping alarms and delaying the whole production cycle. The spurious alarms resulted in much unnecessary downtime that was spent resetting the robots in the hope that another breakdown could be avoided. Each time an alarm was tripped, several hours of production time was lost. “It was for this reason that we were keen to try out ABB’s Remote Service agreement,” said Colin Trevor, plant maintenance manager.Установленные в технологической линии роботы выдавали аварийные сигналы, задерживающие выполнение производственного цикла. Ложные срабатывания вынуждали перезапускать роботов в надежде предотвратить возможные отказы, в результате чего после каждого аварийного сигнала производство останавливалось на несколько часов. «Именно поэтому мы решили попробовать заключить с АББ контракт на дистанционное техническое обслуживание», – сказал Колин Тревор, начальник технической службы фабрики.To prevent future disruptions caused by unplanned downtime, Tetley signed an ABB Response Package service agreement, which included installing a service box and system infrastructure into the robot control systems. Using the Remote Service solution, ABB remotely monitors and collects data on the “wear and tear” and productivity of the robotic cells; this data is then shared with the customer and contributes to smooth-running production cycles.Для предотвращения ущерба в результате незапланированных простоев Tetley заключила с АББ контракт на комплексное обслуживание Response Package, согласно которому системы управления роботами были дооборудованы сервисными блоками с необходимой инфраструктурой. С помощью Remote Service компания АББ дистанционно собирает данные о наработке, износе и производительности роботизированных модулей. Эти данные предоставляются заказчику для оптимизации загрузки производственного оборудования.Higher production uptimeSince the implementation of Remote Service, Tetley has enjoyed greatly reduced robot downtime, with no further disruptions caused by unforeseen problems. “The Remote Service package has dramatically changed the plant,” said Trevor. “We no longer have breakdown issues throughout the shift, helping us to achieve much longer periods of robot uptime. As we have learned, world-class manufacturing facilities need world-class support packages. Remote monitoring of our robots helps us to maintain machine uptime, prevent costly downtime and ensures my employees can be put to more valuable use.”Увеличение полезного времениС момента внедрения Remote Service компания Tetley была приятно удивлена резким сокращением простоя роботов и отсутствием незапланированных остановок производства. «Пакет Remote Service резко изменил ситуацию на предприятии», – сказал Тревор. «Мы избавились от простоев роботов и смогли резко увеличить их эксплуатационную готовность. Мы поняли, что для производственного оборудования мирового класса необходим сервисный пакет мирового класса. Дистанционный контроль роботов помогает нам поддерживать их в рабочем состоянии, предотвращать дорогостоящие простои и задействовать наш персонал для выполнения более важных задач».Service accessRemote Service is available worldwide, connecting more than 500 robots. Companies that have up to 30 robots are often good candidates for the Remote Service offering, as they usually have neither the engineers nor the requisite skills to deal with robotics faults themselves. Larger companies are also enthusiastic about Remote Service, as the proactive services will improve the lifetime of their equipment and increase overall production uptime.Доступность сервисаСеть Remote Service охватывает более 700 роботов по всему миру. Потенциальными заказчиками Remote Service являются компании, имеющие до 30 роботов, но не имеющие инженеров и техников, способных самостоятельно устранять их неисправности. Интерес к Remote Service проявляют и более крупные компании, поскольку они заинтересованы в увеличении срока службы и эксплуатационной готовности производственного оборудования.In today’s competitive environment, business profitability often relies on demanding production schedules that do not always leave time for exhaustive or repeated equipment health checks. ABB’s Remote Service agreements are designed to monitor its customers’ robots to identify when problems are likely to occur and ensure that help is dispatched before the problem can escalate. In over 60 percent of ABB’s service calls, its robots can be brought back online remotely, without further intervention.В условиях современной конкуренции окупаемость бизнеса часто зависит от соблюдения жестких графиков производства, не оставляющих времени для полномасштабных или периодических проверок исправности оборудования. Контракт Remote Service предусматривает мониторинг состояния роботов заказчика для прогнозирования возможных неисправностей и принятие мер по их предотвращению. В более чем 60 % случаев для устранения неисправности достаточно дистанционной консультации в сервисной службе АББ, дальнейшего вмешательства не требуется.ABB offers a flexible choice of service agreements for both new and existing robot installations, which helps extend the mean time between failures, shorten the time to repair and lower the total cost of ownership. With four new packages available – Support, Response, Maintenance and Warranty, each backed up by ABB’s Remote Service technology – businesses can minimize the impact of unplanned downtime and achieve improved production-line efficiency.Компания АББ предлагает гибкий выбор контрактов на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, которые позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и эксплуатационные расходы. Четыре новых пакета на основе технологии Remote Service – Support, Response, Maintenance и Warranty – позволяют минимизировать внеплановые простои и значительно повысить эффективность производства.The benefits of Remote Sevice are clear: improved availability, fewer service visits, lower maintenance costs and maximized total cost of ownership. This unique service sets ABB apart from its competitors and is the beginning of a revolution in service thinking. It provides ABB with a great opportunity to improve customer access to its expertise and develop more advanced services worldwide.Преимущества дистанционного технического обслуживания очевидны: повышенная надежность, уменьшение выездов ремонтных бригад, уменьшение затрат на обслуживание и общих эксплуатационных расходов. Эта уникальная услуга дает компании АББ преимущества над конкурентами и демонстрирует революционный подход к организации сервиса. Благодаря ей компания АББ расширяет доступ заказчиков к опыту своих специалистов и получает возможность более эффективного оказания технической помощи по всему миру.Тематики
- тех. обсл. и ремонт средств электросвязи
Обобщающие термины
EN
Англо-русский словарь нормативно-технической терминологии > remote sevice
75 jockey pump
насос сплинкерной системы пожаротушения
жокей-насос
-Принцип работы насосной установки спринклерной системы пожаротушения, в состав которой входит жокей-насос
В случае падения давления воды в спринклерной системе, первым включается жокей-насос. Если расход воды небольшой и жокей-насос справляется с восполнением утечки, то через некоторое время после достижения верхнего предела заданного давления он выключится. Если же это не протечка, а открылось несколько спринклеров и расход воды значительный, то даже при работающем жокей-насосе давление продолжает падать. В этом случае, по сигналу второго реле давления, включается пожарный насос. Резервный агрегат включается в случае невыхода основного на рабочий режим. Независимо от того, потушен пожар или нет, пожарные насосы сами не отключаются, их можно выключить только вручную со шкафа управления.
[ http://www.airweek.ru/pr_news_137.html]
Jockey Pump
A jockey pump is a small pump connected to a fire sprinkler system and is intended to maintain pressure in a fire protection piping system to an artificially high level so that the operation of a single fire sprinkler will cause an appreciable pressure drop which will be easily sensed by the fire pump automatic controller, causing the fire pump to start. The jockey pump is essentially a portion of the fire pump's control system.
In the U.S.
The application of a jockey pump in a fire protection system is covered by documents produced by the NFPA (National Fire Protection Association,) known as NFPA 20 "Fire Pumps" Standard and NFPA 13 "Design and Installation of Fire Sprinkler Systems". These must be inspected as with any other part of the system per NFPA 25 "Inspection and Testing of Water-Based Fire Protection Systems".Fire protection systems are governed in most states by statute, building code, and/or fire code.
In India
This jockey pump is also a must while designing the Fire Hydrants Pumps skid for Industrial installations.While the logic followed for the effective operation of the fire fighting pumps may depend upon or vary as per the regulations in a particular country, in India, the pump manufacturers like Mather-Platt with standard Fire Pumps generally adhere to the TAC guidelines (Tariff Advisory Committee guidelines).
Although India's premier manufacturer Kirloskar Brothers Limited, with approvals from UL and FM Global, LPCB, ASIB: follows TAC guidelines (Tariff Advisory Committee guidelines), or FM GLobal and UL standards depending on the clients needs.
If one is following the TAC guidelines, follow this approach
*Once the complete fire fighting circuit is under pressure by operating the pumps for sufficient time provided all the fire hydrant valves (Single yard hydrants, Fire escape hydrants, etc)are closed, the main pump stops.
*Due to some leakages somewhere in the fire fighting piping circuit, when there is a loss of system pressure which will be constantly monitored by the Pressure sensors in the circuit, the jockey pumps receives a signal to start from the automatic control panel, and will run to augment this loss of pressure by pumping more water into the circuit. Once the pressure is maintained as per the set point, it stops.
*If any hydrant valve is opened due to some fire and water is consumed, then the jockey pump due to its small capacity compared to the main pumps (one running, one stand-by)in terms of volumetric capacity, the main pump will start and then the jockey immediately stops.This way jockey pump is important which senses the loss of pressure in the circuit first.[ http://en.wikipedia.org/wiki/Jockey_pump#Jockey_Pump]
Тематики
Синонимы
EN
Англо-русский словарь нормативно-технической терминологии > jockey pump
76 point
1) точка2) остриё, острый конец || заострять4) положение; позиция; координата ( рабочего органа)5) указывать; ориентировать, наводить6) место; пункт11) ж.-д. стрелочный перевод; стрелка; остряк, перо ( стрелочного перевода)13) расшивать швы ( кладки)16) пишущий узел, пишущий элемент (ручки, карандаша)17) пищ. оценочный балл•point at infinity — бесконечно удалённая точка;to point off — отводить ( в сторону);to pass through a point — проходить через точку-
Abel flash point
-
acid dew point
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actual point
-
acute round needle point
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addressable point
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adherent point
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aerodrome check point
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aerodrome reference point
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agate arrestment point
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aggregative transition point
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agreed reporting point
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aiming point
-
air supply breathing point
-
aircraft fire point
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alternator pivot point
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anchor point
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anchorage point
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aniline point
-
annealing point
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antinodal point
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aplantic points
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arch work point
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arithmetic point
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array feed point
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assumed point
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attachment point
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automatic point
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azeotropic point
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backoff point
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backward stagnation point
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balance point
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base point
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bend point
-
bending yield point
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binary point
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bleeding point
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bleed point
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blow point
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blunt round needle point
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boiling point
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boundary point
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branch point
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breaker point
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break-in point
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breaking point
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brittle point
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bubble point
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bucking point
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bullet point
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burble point
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burn point
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burning point
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burnout point
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burster point
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cardinal points
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casing point
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central point
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changeover point
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characteristic point
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check point
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chemical-pinch point
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chilling point
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chisel point
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clearing point
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close spread collar point
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closed flash point
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cloud point
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cold point
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collinear points
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collocation point
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common depth point
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compass points
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concyclic points
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condensation point
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congelation point
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consolute point
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consumption point of current
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contact point
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contactor points
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control point
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control transfer point
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corona point
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correct point
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coupler pivot point
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coupling point
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critical point
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crossing point
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crossover point
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cryogen boiling point
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Curie point
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cuspidal point
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cut point
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cutoff point
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cutting point
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datum point
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dead point
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decimal point
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defined point
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delivery point
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demixing point
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dendritic point
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depth reference point
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destination point
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destruction point
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detonation point
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dew point
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dial indicator contact point
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diamond grinding point
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diamond point
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directional kickoff point
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discharge point
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dispatching point
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dispersion point
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distinct curve collar point
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distinct points
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distinguished point
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distribution point
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double point
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drain point
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draw point
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drawoff point
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driving point
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dropping point
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dry point
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dryout point
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early warning point
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edit point
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edit-in point
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edit-out point
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elevation point
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elliptic point
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emission point
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end point
-
energy breakeven point
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entry point
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entry-exit points
-
equal time point
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equilibrium point
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eutectic point
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exclamation point
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exhaustion end point
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exit point
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exterior point
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extraction point
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face point
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fashioning point
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fatigue point
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feeding point
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fiber saturation point
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fiducial point
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filling point
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filling-in point
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film entry point
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film leaving point
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final approach point
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final boiling point
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fine point
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fire point
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firing point
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fixed point
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flame break point
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flare point
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flash point
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flexion point
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flight reference point
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flight way point
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floating point
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floc point
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flooding point
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flow point
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flywheel dead point
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focal point
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forced open point
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forward stagnation point
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fouling point
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freeze point
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freezing point
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French point
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frontier point
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frost point
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fuel injection point
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fuel servicing point
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full point
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fusing point
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gage point
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gaging point
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gas hydrate formation point
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gas point
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geodetic point
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glazier's point
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gloss point
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grasp point
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grid point
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grouped service points
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half point
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hammer point
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hard points
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heat point
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heavy ball needle point
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heavy rounded set needle point
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heavy set needle point
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holding point
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hopper work point
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horizontal control point
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ice point
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ignition point
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image point
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impact point
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incongruent melting point
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index point
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infeed changeover point
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initial point
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injection point
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insertion point
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integral point
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intended landing point
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intercardinal point
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interception point
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intercept point
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interior point
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interlocked point
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isoelectric point
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jacking point
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junction point
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knee point
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laminar separation point
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landfall point of the storm
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last departure point
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lattice point
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leaving point
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leveling point
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level point
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lifter point
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lifting point
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lift-off point
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light ball needle point
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light rounded set needle point
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light set needle point
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limiting point
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limit point
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linking point
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load point
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loading point
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load-unload point
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long collar point
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lower yield point
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lubrication point
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machine home point
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macroyield point
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maker point
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matching point
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matrix point
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maximum power point
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measurement point
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measure point
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medium ball needle point
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melting point
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mesh point
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mid-boiling point
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mixed melting point
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movable point
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multiple point
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needle point
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neutral point
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nodal point
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node point
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noise measurement point
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normal round needle point
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observation point
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open point
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operation point
-
optimum point
-
panel point
-
paper point
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paraffin crystallization point
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peak point
-
pelerine point
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pen point
-
pickup point
-
piercing point
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pile stoppage point
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pinch point
-
pinning point
-
pitch point
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pivotal point
-
pivot point
-
plait point
-
plow point
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point of absolute zero
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point of arrival
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point of contraflexure
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point of curve
-
point of departure
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point of discontinuity
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point of distance
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point of engagement
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point of fault
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point of force application
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point of graph
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point of hook
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point of increase
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point of inflection
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point of intersection
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point of load application
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point of looper
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point of maximum
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point of minimum
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point of no return
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point of occlusion
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point of sight
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point of support
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point of tangency
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point of tree
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porous point
-
pour point
-
power point
-
precision point
-
preroll point
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primary calibration point
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principal point
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probe point
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projected peak point
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pullout point
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quadrantal point
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quarter-span point
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quarter point
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quiescent operating point
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radix point
-
reaction point
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receiving point
-
reentry point
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reference point
-
reflection depth point
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refraction depth point
-
regional heat point
-
reporting point
-
rerun point
-
ripper point
-
rounded set needle point
-
saddle point
-
salient point
-
saturation point
-
sectioning point
-
set needle point
-
set point
-
setting point
-
shot point
-
sighting point
-
singing point
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single defect point
-
single point
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singular point
-
sintering point
-
slinging point
-
smoke point
-
softening point
-
solder termination point
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solidification point
-
source point
-
special ball needle point
-
spring point
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square collar point
-
stable point
-
stadia point
-
stagnation point
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star point
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stationary breaker point
-
stitch transfer point
-
stuck point
-
subsatellite point
-
support point
-
surveying point
-
survey point
-
switch point
-
switching point
-
takeoff point
-
tangent point
-
tapping point
-
terminal point
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termination point
-
test point
-
thaw point
-
thermal critical point
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thermodynamic point
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third point
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threshold point
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tie point
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toll point
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tool point
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touch point
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touchdown point
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towing point
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tow point
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trailing point
-
transfer initiation point
-
transfer point
-
transformation point
-
transit point
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transition point
-
trap point
-
triangulation point
-
triple point
-
tripping point
-
true molal boiling point
-
turning point
-
umbilical point
-
unload point
-
unloading point
-
upper yield point
-
valley point
-
vanishing point
-
vertical control point
-
visible point
-
vitrifying point
-
volumetric boiling point
-
water supply point
-
wax dropout point
-
weight boiling point
-
weight-drop point
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well point
-
wiring point
-
word break point
-
working point
-
yield point
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Y-point
-
zero point77 signal
1) сигнал || сигнализировать, передавать сигналы2) оповещение3) событие ( в программе)•-
absolute stop signal
-
accelerating signal
-
accompanying sound signal
-
acknowledgement signal
-
acoustic signal
-
actuating signal
-
addressing signal
-
address signal
-
advance signal
-
alarm signal
-
alternate mark inversion signal
-
amplitude-modulated signal
-
amplitude-shift keyed signal
-
analog signal
-
angle-modulated signal
-
anisochronous signal
-
antipodal signal
-
arrival signal
-
attention signal
-
audible signal
-
audio signal
-
axis designation signal
-
B signal
-
background signal
-
back-to-normal signal
-
backup signal
-
band-limited signal
-
baseband signal
-
beam indexing signal
-
bell signal
-
bidirectional signal
-
binary signal
-
bipolar signal
-
black signal
-
black-and-white signal
-
blackout signal
-
blanketing signal
-
blanking signal
-
blank-out signal
-
blocking signal
-
block-section signal
-
bracket signal
-
brightness signal
-
broadband signal
-
broadcasting television signal
-
busy back signal
-
busy signal
-
B-Y signal
-
cab signal
-
calibration signal
-
calling-on signal
-
call-on signal
-
carry signal
-
caution signal
-
chirp signal
-
chroma signal
-
clear signal
-
clear-back signal
-
clear-forward signal
-
clearing signal
-
clipped signal
-
clock signal
-
code signal
-
color bar signal
-
color burst sync signal
-
color identification signal
-
color signal
-
color television signal
-
color-difference signal
-
color-separation signal
-
common-mode signal
-
complete video signal
-
composite color video signal
-
composite picture signal
-
composite synchronization signal
-
composite video signal
-
compressed signal
-
conflicting signal
-
constant-amplitude signal
-
contact detection signal
-
contaminating signal
-
continuous-phase signal
-
control signal
-
convolved signal
-
correlated signal
-
critical axis distance signal
-
cross-hatch signal
-
crosstalk signal
-
cue signal
-
danger signal
-
dark signal
-
data signal
-
day signal
-
decadic signal
-
decrease signal
-
departure signal
-
detected signal
-
detection signal
-
deterministic signal
-
difference signal
-
differential-mode signal
-
digital signal
-
digital television signal
-
digital video signal
-
directional signal
-
directivity signal
-
disable signal
-
discernible signal
-
disconnect signal
-
disk signal
-
distance-representing signal
-
distant switch signal
-
distinguishable signal
-
dither signal
-
diversity signal
-
Doppler-shift signal
-
Doppler signal
-
double-sideband signal
-
drive signal
-
driving signal
-
dwarf semaphore signal
-
echoed signal
-
echo signal
-
emergency signal
-
enable signal
-
enciphered signal
-
end-of-impulsing signal
-
end-of-pulsing signal
-
end-of-conversion signal
-
engage signal
-
erase signal
-
error signal
-
facsimile signal
-
failed signal
-
false signal
-
fault signal
-
feed stop signal
-
feedback signal
-
field synchronization signal
-
filtered signal
-
fixed signal
-
flashing signal
-
flight urgency signal
-
floodlight signal
-
fluctuating signal
-
fog repeater signal
-
foreground signal
-
four-aspect signal
-
free-line signal
-
frequency-hopped signal
-
frequency-modulated signal
-
frequency-shift keyed signal
-
friendly signal
-
G signal
-
gate signal
-
gating signal
-
ghost signal
-
grade signal
-
grinding torque error signal
-
ground signal
-
guard signal
-
hand signal
-
hang-up signal
-
high-level signal
-
holding signal
-
home signal
-
homing signal
-
hopping signal
-
hump light signal
-
hump signal
-
I signal
-
identification signal
-
ident signal
-
idle identification signal
-
impulse signal
-
increase signal
-
inhibiting signal
-
initiate shift signal
-
in-phase signal
-
in-position signal
-
input signal
-
insertion test signal
-
interface signal
-
interfering signal
-
interlocked signal
-
intermediate signal
-
interrupt signal
-
isochronous signal
-
jamming signal
-
junction signal
-
keying signal
-
leave signal
-
left-hand signal
-
level crossing signal
-
light signal
-
limited signal
-
line clear signal
-
line signal
-
line synchronization signal
-
line-frequency control signal
-
line-identification signal
-
locked-on signal
-
locking signal
-
logic signal
-
longitudinal time and control signal
-
low-level signal
-
luminance signal
-
main home signal
-
marshaling signal
-
medium-approach signal
-
microwave signal
-
minimum-phase signal
-
mixed synchronization signal
-
modulating signal
-
monitoring signal
-
monitor signal
-
motion signal
-
multiburst signal
-
multichannel signal
-
multiple frequency signal
-
multiplexed signal
-
narrow-band signal
-
night signal
-
noise signal
-
noise-free signal
-
noise-like signal
-
nominal white signal
-
nonband-limited signal
-
nonminimum-phase signal
-
normal-mode signal
-
numeral signal
-
off/on signal
-
off-hook signal
-
on-hook signal
-
opposing signal
-
output signal
-
PAL line-identification signal
-
partial-response signal
-
permissive signal
-
phase-modulated signal
-
phase-shift keyed signal
-
pickup signal
-
picture signal
-
pilot signal
-
playback signal
-
point signal
-
polar signal
-
position error signal
-
position signal
-
prescribed signal
-
pressure feedback signal
-
probe's signal
-
probe signal
-
probing signal
-
proceed signal
-
protection signal
-
pseudonoise signal
-
pseudorandom signal
-
pseudo-ternary signal
-
pulse and bar signal
-
pulsed signal
-
pulse signal
-
Q signal
-
quadrature signal
-
quantized signal
-
R signal
-
radio-frequency signal
-
radio signal
-
random signal
-
ranging signal
-
reading signal
-
read signal
-
rectified signal
-
reference signal
-
reference white signal
-
reminder signal
-
request signal
-
restrictive signal
-
retract signal
-
return video signal
-
returned signal
-
return signal
-
RGB signal
-
right-hand signal
-
ring signal
-
ring-back signal
-
road crossing signal
-
robust signal
-
route signal
-
run-in signal
-
R-Y signal
-
safety signal
-
sampled signal
-
saw-tooth signal
-
scrambled signal
-
searchlight signal
-
seizing signal
-
sense signal
-
series-mode signal
-
service signal
-
shading compensation signal
-
shadow signal
-
shunt signal
-
signal of distress
-
silhouette signal
-
sine signal
-
single-sideband signal
-
sinusoidal signal
-
sonar signal
-
sound signal
-
sounding signal
-
sound-program signal
-
speech signal
-
spread-spectrum signal
-
spurious signal
-
square-wave signal
-
square signal
-
start signal
-
starting signal
-
start-stop signal
-
startup signal
-
station light signal
-
stop signal
-
stop-and-proceed signal
-
strobe signal
-
suppressed-carrier signal
-
swept signal
-
switch signal
-
synchronizing signal
-
sync signal
-
system pressure signal
-
target signal
-
television broadcast signal
-
television sound signal
-
test line signal
-
test signal
-
testing signal
-
test-pattern signal
-
three-aspect signal
-
through signal
-
time signal
-
time-and-control signal
-
timing signal
-
tool change signal
-
track signal
-
train order signal
-
train tail signal
-
transverse-mode signal
-
triggering signal
-
trigger signal
-
trouble signal
-
tunnel signal
-
two-head signal
-
two-position signal
-
U signal
-
undesired signal
-
unvoiced signal
-
unwanted signal
-
urgent signal
-
V signal
-
velocity feedback signal
-
velocity signal
-
vertical interval test signal
-
vestigial sideband signal
-
video signal
-
visible signal
-
voice signal
-
voiced signal
-
W signal
-
warning signal
-
wayside automatic signal
-
wayside signal
-
weather signal
-
wideband signal
-
window signal
-
write signal
-
Y signal78 point
1) пункт
2) запятая
3) кегль
4) острие
5) острый конец
6) очко
7) расшивать
8) расшить
9) точечный
10) шпицевать
11) деление
12) <topogr.> мыс
13) точка
14) место
15) указывать
16) ставить знаки препинания
17) заострение
18) наконечник
19) предмет
20) <engin.> балл
– accessible point
– accumulation point
– adherent point
– altimetric point
– ambiguous point
– amplitude of a point
– anchoring point
– antipodal point
– at a point
– at point
– attaching point
– attachment point
– automatic set point
– barometrical point
– base point
– bending point
– binary point
– boiling point
– boundary point
– branch point
– branching point
– breaker point
– brilliant point
– burble point
– cardinal point
– center point
– check point
– chisel point
– compass-card point
– condensation point
– conjugate point
– contact point
– continuous at a point
– contraction to point
– convergence point
– corner point
– cultivator point
– Curie point
– cuspidal point
– cut point
– cutter point
– data point
– datum point
– dead point
– decimal point
– degree of point
– departure point
– dew point
– diacritical point
– diamond point
– diramation point
– discontinuity point
– divider point
– dividing point
– double point
– drill point
– east point
– enclose a point
– entry point
– equilibrium point
– equivalence point
– evaporating point
– extra-axis point
– extreme point
– finishing point
– firing point
– fix point in position
– fixed point
– flash point
– flex point
– floating point
– form point
– freezing point
– fusion point
– generic point
– glass-transition point
– glaziers' point
– gold point
– grid point
– half-power point
– hinge point
– ice formation point
– ideal point
– ignition point
– image of a point
– indication point
– infinite point
– inflection point
– initial point
– intersection point
– inverse point
– isolated point
– junction point
– labile point
– lattice point
– limit point
– linkage point
– load point
– lubrication point
– main point
– mark a point
– marker point
– mass point
– material point
– measuring point
– melting point
– mirror point
– movable point
– multiple point
– nadir point
– Neel point
– neutral point
– nodal point
– north point
– null point
– operating point
– pitch point
– point approximation
– point at infinity
– point bar
– point brilliance
– point cathode
– point conic
– point contact
– point contacts
– point corrosion
– point diode
– point disturbance
– point eikonal
– point focus
– point force
– point harmonic
– point hologram
– point in time
– point joints
– point lock
– point locking
– point mass
– point of application
– point of break
– point of connection
– point of contact
– point of control
– point of departure
– point of destination
– point of emanation
– point of inflection
– point of interpolation
– point of intersection
– point of junction
– point of lattice
– point of levelling
– point of observation
– point of osculation
– point of reference
– point of separation
– point of sight
– point of support
– point of tangency
– point of the compass
– point of tooth
– point of view
– point pile
– point radiator
– point resolution
– point scale
– point scatterer
– point set
– point source
– point spectrum
– point temperature
– point tool
– point wire
– position of a point
– power of a point
– precipitation point
– principal point
– radix point
– rail point
– ramification point
– reefing point
– reference point
– regular point
– ridge point
– saddle point
– sampling point
– saturation point
– sense point
– separation point
– sequence point
– share point
– silver point
– singing point
– singular point
– softening point
– solidification point
– spark-plug point
– spinodal point
– spiral point
– sputter point
– stagnation point
– starting point
– stationary point
– stock point
– switching point
– terminal point
– tooth point
– touch-down point
– transfer point
– transformation point
– transition point
– triangulation point
– triple point
– turning point
– umbilical point
– unit point
– up to this point
– valley point
– vanishing point
– work point
– world point
– yield point
– zenith point
azimuth of distant point — <topogr.> азимут направления на отдаленную наблюдаемую
bisecting point of a segment — <geom.> середина отрезка
control point adjustment — настройка точки регулирования, <engin.> задатчик
facing point lock — < railways> замок ригельный оконечный
fixed point computation — вычисление с фиксированной запятой
floating decimal point — <comput.> точка плавающая
including the point at infinity — включая бесконечно удаленную точку
phase separation point — <phys.> критическая точка расслаивания
point spread function — <opt.> функция аппаратная, <opt.> функция рассеяния точки
true boiling point — <phys.> температура кипения истинная
79 OAC
1) Общая лексика: кислородно дуговая резка (процесс газовой резки, который использует дугу между рабочей деталью и плавким электродом, через который кислород подается на рабочую деталь. Для металлов, устойчивых к окислению, химический флюс или металлический порошо)2) Спорт: Ohio Athletic Conference3) Военный термин: Objective Architecture Center, Ordnance Ammunition Command, officer advanced course, operating agency code, operations analysis center, operations analysis chief, optimum approach course, own action4) Техника: observation, analysis and control, office allegation coordinator, optimal automatic control5) Юридический термин: Ohio Administrative Code, Office of the Administrator for the Courts (Washington)6) Бухгалтерия: On Approved Credit7) Грубое выражение: Official Assholes Club8) Сокращение: Oceanic Area Control9) Университет: Ontario Academic Credit, Ontario Academic Credits10) Электроника: Optical Absorption Coefficient11) Биохимия: Optimally Adaptive Control12) Океанография: Oceanographic Advisory Committee13) Медицинская техника: open aortic commissurotomy (ЭхоКГ)14) Международная торговля: Office of Anti-boycott Compliance80 computer
3) картограф•-
air data computer
-
airborne computer
-
analog computer
-
analog-digital computer
-
approach computer
-
asynchronous computer
-
auto go-round computer
-
automatic dead reckoning computer
-
back-end computer
-
bearing-distance computer
-
business-oriented computer
-
business computer
-
card-programmed computer
-
cell computer
-
central computer
-
centralized process computer
-
commercial computer
-
communication computer
-
concurrent computer
-
control computer
-
course computer
-
database computer
-
data-flow computer
-
dead-reckoning computer
-
dedicated computer
-
desk-top computer
-
digital computer
-
distributed-logic computer
-
DNC computer
-
Doppler computer
-
drive computer
-
embedded computer
-
exposure computer
-
fixed-program computer
-
flight computer
-
flow computer
-
FMS computer
-
front-end computer
-
gateway computer
-
general-purpose computer
-
guidance computer
-
hand-held computer
-
high-end computer
-
high-performance computer
-
high-speed computer
-
home computer
-
host computer
-
hybrid computer
-
image computer
-
incremental computer
-
inertial navigation computer
-
interface computer
-
keyboard computer
-
knowledge base computer
-
laptop computer
-
large-scale computer
-
large computer
-
low-end computer
-
machine's computer
-
mainframe computer
-
main-line computer
-
master computer
-
multiprogrammed computer
-
navigational computer
-
navigation computer
-
node computer
-
office computer
-
overriding computer
-
overshoot computer
-
parallel computer
-
part-programming computer
-
peripheral computer
-
personal computer
-
pneumatic analog computer
-
portable computer
-
process control computer
-
professional computer
-
real-time computer
-
repetitive computer
-
satellite computer
-
scheduling computer
-
scientific computer
-
self-contained computer
-
sensor-based computer
-
serial computer
-
single-board computer
-
slave computer
-
small computer
-
special-purpose computer
-
special computer
-
stability computer
-
standby computer
-
station's own computer
-
stored-program computer
-
subscriber computer
-
super computer
-
supervisory computer
-
synchronous computer
-
table-top computer
-
timeshared computer
-
traffic control computer
-
universal computer
-
vector computer
-
virtual computer
-
wired-program computerСтраницыСм. также в других словарях:
Automatic Train Control — Der Begriff Automatic Train Control bezeichnet eine Reihe verschiedener Zugsicherungssysteme. In der englischen Herkunftssprache steht ATC (Automatic Train Control) für Systeme, die über die streckenseitige Zugsicherung ATS (Automatic Train Stop) … Deutsch Wikipedia
automatic approach and landing — A control mode in which the aircraft’s speed and flight path are automatically controlled for approach, flare out, and landing. The same as autoland approach … Aviation dictionary
automatic approach and landing — A control mode in which the aircraft … Military dictionary
Automatic Block Signal — Basic Automatic Block Signals = Automatic Block Signal, or ABS, systems consist of a series of signals that govern blocks of track between the signals. The signals are automatically activated by the conditions of the block beyond the signal.… … Wikipedia
Automatic Warning System — The Automatic Warning System (AWS) is a form of limited cab signalling and train protection system introduced in 1956 in the United Kingdom to help train drivers observe and obey signals. It was based on a 1930 system developed by Alfred Ernest… … Wikipedia
automatic pilot — 1. Aeron. an airborne electronic control system that automatically maintains a preset heading and attitude. Also called automatic, autopilot, gyropilot, robot. 2. on automatic pilot, functioning in an unthinking or reflexive manner. [1915 20] * * … Universalium
approach coupler — An electronic linkage between the ILS (instrument landing system), the automatic flight control, and the autopilot … Aviation dictionary
Automatic summarization — is the creation of a shortened version of a text by a computer program. The product of this procedure still contains the most important points of the original text. The phenomenon of information overload has meant that access to coherent and… … Wikipedia
Automatic dependent surveillance-broadcast — (ADS B) is a cooperative surveillance technique for air traffic control and related applications. An ADS B out equipped aircraft determines its own position using a global navigation satellite system and periodically broadcasts this position and… … Wikipedia
Control reconfiguration — is an active approach in control theory to achieve fault tolerant control for dynamic systems [1]. It is used when severe faults, such as actuator or sensor outages, cause a break up of the control loop, which must be restructured to prevent… … Wikipedia
Automatic Terminal Information Service — Automatic Terminal Information Service, or ATIS, is a continuous broadcast of recorded noncontrol information in busier terminal (i.e. airport) areas. ATIS broadcasts contain essential information, such as weather information, which runways are… … Wikipedia
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