Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Quantum electronics. --- Electronic noise. --- Bruit électronique --- Électronique quantique

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Electronic noise --- Bruit électronique --- Congresses --- Congrès --- Congresses. --- Bruit électronique --- Congrès

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Electronics --- Electronic noise --- Bruit électronique --- 621.391.8 --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Quality of the received signal. Signal strength. Interference --- 621.391.8 Quality of the received signal. Signal strength. Interference --- Bruit électronique

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Digital filters (Mathematics) --- Electronic noise --- Signal processing --- #TWER:MOD --- #TELE:SISTA --- Processing, Signal --- Information measurement --- Signal theory (Telecommunication) --- Noise, Electronic --- Electric noise --- Data smoothing filters --- Filters, Digital (Mathematics) --- Linear digital filters (Mathematics) --- Linear filters (Mathematics) --- Numerical filters --- Smoothing filters (Mathematics) --- Digital electronics --- Filters (Mathematics) --- Fourier transformations --- Functional analysis --- Numerical analysis --- Numerical calculations --- Traitement du signal --- Bruit électronique --- Filtres numériques (mathématiques) --- Traitement du signal. --- Bruit électronique. --- Bruit électronique. --- Filtres numériques (mathématiques)

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

It is hardly a revelation to note that wireless and mobile communications have grown tremendously during the last few years. This growth has placed stringent requi- ments on channel spacing and, by implication, on the phase noise of oscillators. C- pounding the challenge has been a recent drive toward implementations of transceivers in CMOS, whose inferior 1/f noise performance has usually been thought to disqualify it from use in all but the lowest-performance oscillators. Low noise oscillators are also highly desired in the digital world, of course. The c- tinued drive toward higher clock frequencies translates into a demand for ev- decreasing jitter. Clearly, there is a need for a deep understanding of the fundamental mechanisms g- erning the process by which device, substrate, and supply noise turn into jitter and phase noise. Existing models generally offer only qualitative insights, however, and it has not always been clear why they are not quantitatively correct.

Oscillators, Electric --- Electronic circuits --- Electronic noise --- Radio frequency oscillators --- Oscillateurs --- Circuits électroniques --- Bruit électronique --- Oscillateurs haute fréquence --- Design and construction --- Noise --- Conception et construction --- Bruit --- -Electronic noise --- -Radio frequency oscillators --- RF oscillators --- Electric oscillators --- Electric apparatus and appliances --- Electric machinery --- Radio --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Electron-tube circuits --- Electric circuits --- Electron tubes --- Electronics --- Computer engineering. --- Design and construction. --- Electronic circuits. --- Electronic noise. --- Engineering. --- Noise. --- Oscillators, Electric. --- Oscillators. --- Electrical & Computer Engineering --- Engineering & Applied Sciences --- Electrical Engineering --- Radio frequency oscillators. --- Circuits électroniques --- Bruit électronique --- Oscillateurs haute fréquence --- EPUB-LIV-FT SPRINGER-B --- Electrical engineering. --- Circuits and Systems. --- Electrical Engineering. --- Systems engineering. --- Noisy circuits --- Electric engineering --- Engineering --- Oscillators, Electric - Design and construction --- Electronic circuits - Noise