Journal of the Franklin Institute, Volume 249Pergamon Press, 1950 |
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Page 57
... load impedance . Necessary and sufficient conditions are derived for the physical realizability of a function of frequency representing the input reflection coeffi- cient of a matching network terminated in a prescribed load impedance ...
... load impedance . Necessary and sufficient conditions are derived for the physical realizability of a function of frequency representing the input reflection coeffi- cient of a matching network terminated in a prescribed load impedance ...
Page 58
... load impedance and a given maximum tolerance , there is an upper limit to the bandwidth that can be obtained by means of a physically realizable coupling net- work . It follows that an investigation of such a limit should be the first ...
... load impedance and a given maximum tolerance , there is an upper limit to the bandwidth that can be obtained by means of a physically realizable coupling net- work . It follows that an investigation of such a limit should be the first ...
Page 151
... load impedance of 10 ohms and a source impedance of 1000 ohms . The same design technique can be applied to the case of a load con- sisting of a series ( or parallel ) tuned circuit if the frequency band over which the load is to be ...
... load impedance of 10 ohms and a source impedance of 1000 ohms . The same design technique can be applied to the case of a load con- sisting of a series ( or parallel ) tuned circuit if the frequency band over which the load is to be ...
Contents
MARCH 1950 No | 3 |
MAY 1950 No | 5 |
A Note on the Notch Effect of Metals K MINAMIŌZI AND H ŌKUBO | 49 |
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acid angle application approximation axial axial stress Board of Managers boron trifluoride Cavendish chemistry Committee components computing constant contours corresponding curve deformation theories density diagram discussed Dm(t E₁ edition electrical electronics emulsion engineering equations equipment example experimental field fracture Franklin Institute frequency function given heat hyperbolic hyperbolic angle hyperbolic functions illustrations imaginary axis impedance industrial interest investigation isoprene k₁ laboratory limit load magnetic amplifier matching network material mechanics metal method obtained octahedral strain octahedral theory operating oscilloscope p₁ paper photographs physical plastic plate poles practical presented President principal stresses problems radiation radius vector ratio reflection coefficient relations Section shear stress sinh solution stress-strain curve technical techniques temperature tion transformer transmission coefficient tube types unit variable voltage wave X-plane zero of transmission