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diffraction effects(passive) caused byYonglin Insertion loss
the first filter(passive) caused byan insertion loss
the filter additioncausesan insertion loss
filter 310(passive) caused bythe insertion loss
the bandpass filter(passive) caused byThe insertion loss
the filter selection switch and the attenuator(passive) caused byinsertion losses
the band - stop filter(passive) caused byinsertion loss
the tunable filter 250(passive) caused bythe insertion loss
cable capacitance , which acts as a low - pass filter , blocking higher frequency signal components from passing(passive) is caused byInsertion loss
cable capacitance acting as a low - pass filter(passive) is caused byInsertion loss
the change of the electromagnetic field distributions of the two transmission lines at their transition(passive) caused bythe insertion loss
parasitic capacitance between device and substrate , ( ii(passive) caused bythe insertion loss
the optical switching device and the circulator 5(passive) caused byan insertion loss
the high - pass filter in a frequency range in which a transmission phase difference is given to an RF signal passing through the high - pass filter.2011 - 12 - 15 20110304410Filter Circuit(passive) caused byinsertion loss
Every RF connectorcausesinsertion loss Answer
the tunable filter in the cellular frequency band(passive) caused byinsertion loss
this filter ... though worsening the filtering characteristics asinfluencesthe insertion loss
the diplexer(passive) caused bythe insertion loss
degradation of the signal to be radiated and in return losses(passive) caused byinsertion losses
the serial connection of switch circuits(passive) caused bythe insertion loss
the optical attenuator 10(passive) created bythe insertion loss
optical fibers 321(passive) caused bythe insertion loss
multiple reflections(passive) caused bythe insertion loss
long optical path length(passive) caused bythe insertion loss
These losses tendto causeinsertion loss
resistive losses(passive) caused bythe insertion loss
the switches and cables(passive) caused bythe insertion loss
the ON - resistance of the switch when either one of band 1 or band 2 is used(passive) caused bythe insertion loss
the impedance mismatch(passive) caused bythe insertion loss
misalignment of the cores of their optical fibers(passive) caused byinsertion losses
Fresnel reflection and by misalignment of the fibres(passive) is caused byan insertion loss
the switch configuration shown above so that you can accurately calculate the insertion loss caused by the DUT(passive) caused bythe insertion loss
the electric resistance of the conductor pattern(passive) caused bythe insertion loss
the attenuator , which increases the attenuation of the input signal(passive) caused bythe insertion loss
shortening the whole length of the optical attenuator(passive) caused bythe insertion loss
undesirable reflections and refractionscauseinsertion loss
the test string of components(passive) caused bythe insertion loss
the former optical components(passive) caused bythe insertion loss
the attenuator 214 n to maximum based on the channel(passive) caused bythe insertion loss
the attenuator 165 n of the channel CH - n(passive) caused bythe insertion loss
from absorption , misalignment or air gap between the fiber optic components. Return Losscan resultfrom absorption , misalignment or air gap between the fiber optic components. Return Loss
from the varactorsresultingfrom the varactors
from an air space which exists between the lens 104 and the reflector 106resultingfrom an air space which exists between the lens 104 and the reflector 106
to power reduction in the transmitted downlink beamsleadsto power reduction in the transmitted downlink beams
from the combined 90 180 FIGresultingfrom the combined 90 180 FIG
from the application of an additional capacitorresultingfrom the application of an additional capacitor
power consumption of the mobile communication terminal equipment including the SAW elementinfluencespower consumption of the mobile communication terminal equipment including the SAW element
to the optical signal by the optical switch cellcausedto the optical signal by the optical switch cell
from the combined 90 � and 180 � hybrid circuits 41resultingfrom the combined 90 � and 180 � hybrid circuits 41
from the combined 90 � and 180 � hybrid circuits shown in FIGresultingfrom the combined 90 � and 180 � hybrid circuits shown in FIG
from using these materialsresultingfrom using these materials
to an increase in the system noise figurecan ... leadto an increase in the system noise figure
the signaling problems(passive) caused bythe signaling problems
from pair three and FEXT resulting from the interaction between pairs three and fourresultingfrom pair three and FEXT resulting from the interaction between pairs three and four
desensitization problems in the multicouplercreatedesensitization problems in the multicoupler
from pair two and FEXT resulting from the interaction between pair two and pairs three and fourresultingfrom pair two and FEXT resulting from the interaction between pair two and pairs three and four
from the combined 90 180 measured insertion phase resulting from the combined 90 180 traces , which correspond to the four outputs of the combined circuitresultingfrom the combined 90 180 measured insertion phase resulting from the combined 90 180 traces , which correspond to the four outputs of the combined circuit
the receiver to be less sensitive and have a higher noise figure for these radio frequency bandscan causethe receiver to be less sensitive and have a higher noise figure for these radio frequency bands
by using MEMS VOAs in the switch assemblycausedby using MEMS VOAs in the switch assembly
from pair one and FEXT resulting from the interaction between pair one and pairs two , threeresultingfrom pair one and FEXT resulting from the interaction between pair one and pairs two , three
to rising edge degradation of signals or higher rate bit error and so oncould leadto rising edge degradation of signals or higher rate bit error and so on
from a mode mismatchresultingfrom a mode mismatch
in the experimentcausedin the experiment
in heatresultingin heat
to poor performancecontributesto poor performance
network failuresdramatically causingnetwork failures
from the insertion of additional devices , which spreads the signal thinresultsfrom the insertion of additional devices , which spreads the signal thin
with less light passing through than is desiredtypically resultswith less light passing through than is desired
from the absorption , misalignment or air gap between the optical fiber componentscan resultfrom the absorption , misalignment or air gap between the optical fiber components
from absorption , misalignment or air gap between the fibre optic componentscan resultfrom absorption , misalignment or air gap between the fibre optic components
in failure to provide a suitable optical connection or reduction in bandwidthcan resultin failure to provide a suitable optical connection or reduction in bandwidth
in the feedthroughcreatedin the feedthrough
in an attenuated signal at -6.7resultsin an attenuated signal at -6.7
from splice optical fibers with dissimilar core diametersresultingfrom splice optical fibers with dissimilar core diameters
into the component or by unintentional intrinsic material losses or scattering to other parts of the packageintentionally designedinto the component or by unintentional intrinsic material losses or scattering to other parts of the package
from stray capacitanceresultingfrom stray capacitance
to a closed eye diagram compared to this eyeleadingto a closed eye diagram compared to this eye
signals to lose strength as they go through multiple dielectric layers ( metal resistancecausessignals to lose strength as they go through multiple dielectric layers ( metal resistance
gain input PACblock 'ssettinggain input PACblock 's
from the reduction in mode field sizeresultingfrom the reduction in mode field size