Noise in Solid State Devices and CircuitsGives basic and up-to-date information about noise sources in electronic devices. Demonstrates how this information can be used to calculate the noise performance, in particular the noise figure, of electronic circuits using these devices. Optimization procedures, both for the circuits and for the devices, are then devised based on these data. Gives an elementary treatment of thermal noise, diffusion noise, and velocity-fluctuation noise, including quantum effects in thermal noise and maser noise. |
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Page 19
... Nyquist's theorem , 15 and the second half follows immediately by applying linear circuit theory to the problem . We thus see that the equipartition theorem allows us to solve the problem completely . We have also proved Nyquist's theorem ...
... Nyquist's theorem , 15 and the second half follows immediately by applying linear circuit theory to the problem . We thus see that the equipartition theorem allows us to solve the problem completely . We have also proved Nyquist's theorem ...
Page 63
... Nyquist's theorem for the thermal noise of a resistance R at a temperature T led to the following expression for the available thermal noise power in a frequency interval △ f : Sv ( f ) Af_ Pav = = kT Af 4R ( 5.1 ) We first shall prove ...
... Nyquist's theorem for the thermal noise of a resistance R at a temperature T led to the following expression for the available thermal noise power in a frequency interval △ f : Sv ( f ) Af_ Pav = = kT Af 4R ( 5.1 ) We first shall prove ...
Page 65
... Nyquist's theorem for high frequencies and low temperatures . Nyquist's theorem in its low - frequency form therefore holds for any resistance , whatever its origin , provided that it is in equilibrium with a temperature bath at a ...
... Nyquist's theorem for high frequencies and low temperatures . Nyquist's theorem in its low - frequency form therefore holds for any resistance , whatever its origin , provided that it is in equilibrium with a temperature bath at a ...
Contents
INTRODUCTION | 1 |
MATHEMATICAL METHODS | 7 |
NOISE CHARACTERIZATION | 25 |
Copyright | |
10 other sections not shown
Common terms and phrases
AN² average calculate capacitance carriers channel conductance constant density device device under test diffusion noise drain effect emitter energy equation equivalent circuit equivalent noise equivalent noise temperature flicker noise fluctuating Fmin frequency function g-r noise g(Vo G₁ GaAs gmax Hence holes IEEE Trans injection input circuit integral JFET low-frequency maser mixer mobility-fluctuation MOSFET n-Channel N₁ N₂ noise current noise figure noise measure noise power noise resistance noise source noise temperature Nougier Nyquist's theorem p-region P. H. Handel parameter Phys processes quantum 1/f noise R₁ recombination resistor S₁(f screen grid section Ax semiconductor short-circuited shot noise signal silicon SN(f Solid State Electron space-charge region spectrum T₁ theorem theory thermal noise transistor trap tunnel diode Umklapp V₁ voltage yields Ysat zero Ziel απ