Active Analog Filter Laboratory
... 5. Double click on the sinusoidal source block and change the amplitude to 5. Note: The program does not need to be recompiled when changing the sinusoidal source amplitude, frequency, or off set. Set the frequency of the sinusoidal source to the calculated cutoff frequency (in rad/s). 6. Click the ...
... 5. Double click on the sinusoidal source block and change the amplitude to 5. Note: The program does not need to be recompiled when changing the sinusoidal source amplitude, frequency, or off set. Set the frequency of the sinusoidal source to the calculated cutoff frequency (in rad/s). 6. Click the ...
Is 24-bit better than 16-bit for Data Acquisition Applications
... poor and unpredictable signal fidelity means it cannot be trusted to measure a peak on any fast edge. On the other hand, a wideband oscilloscope will suffer from aliasing if used for FFT measurements. To overcome this contradiction, the best instruments provide software selection between Gaussi ...
... poor and unpredictable signal fidelity means it cannot be trusted to measure a peak on any fast edge. On the other hand, a wideband oscilloscope will suffer from aliasing if used for FFT measurements. To overcome this contradiction, the best instruments provide software selection between Gaussi ...
ECE 331: Electronics Principles Differential and Integral Calculus
... - Large-signal processing (clamps, logic inverters) - Linear signal processing (linear amplifiers, filters) ...
... - Large-signal processing (clamps, logic inverters) - Linear signal processing (linear amplifiers, filters) ...
The ”digital” ADC
... The frequency-modulated frequency-to-digital converter (FDSM) may cope with technology scaling and lower supply voltages of state-of-the-art digital technology and to a minor extend is suffering of the SQNR-squeezing known from traditional AM modulated systems mostly used today. These results are ba ...
... The frequency-modulated frequency-to-digital converter (FDSM) may cope with technology scaling and lower supply voltages of state-of-the-art digital technology and to a minor extend is suffering of the SQNR-squeezing known from traditional AM modulated systems mostly used today. These results are ba ...
RC Filter and Basic Timer Functionality
... board clock or some other external clock signal), how it should count, and whether it should behave as an up, down, or up-down counter. The ATmega328 features two 8-bit counters (Timer0 and Timer2) and one 16-bit counter (Timer1), and the resolution of each counter may optionally be modified by the ...
... board clock or some other external clock signal), how it should count, and whether it should behave as an up, down, or up-down counter. The ATmega328 features two 8-bit counters (Timer0 and Timer2) and one 16-bit counter (Timer1), and the resolution of each counter may optionally be modified by the ...
BDTIC
... and production costs. This device supports your applications requiring frequency resolution down to 7 Hz and data rates up to 100kbit/s including data encoding, at the chip level for the most popular standards. Gain from design, speed and flexibility by using this fully programmable, high‑performanc ...
... and production costs. This device supports your applications requiring frequency resolution down to 7 Hz and data rates up to 100kbit/s including data encoding, at the chip level for the most popular standards. Gain from design, speed and flexibility by using this fully programmable, high‑performanc ...
IOSR Journal of Electrical and Electronics Engineering (IOSR-JEEE)
... negative DC (Direct Current) voltage is applied at the output. Over the period of one triangle wave, the average voltage applied to the load is proportional to the amplitude of the signal (assumed constant) during this period. The resulting chopped square waveform contains a replica of the desired w ...
... negative DC (Direct Current) voltage is applied at the output. Over the period of one triangle wave, the average voltage applied to the load is proportional to the amplitude of the signal (assumed constant) during this period. The resulting chopped square waveform contains a replica of the desired w ...
Chirp spectrum
The spectrum of a chirp pulse describes its characteristics in terms of its frequency components. This frequency-domain representation is an alternative to the more familiar time-domain waveform, and the two versions are mathematically related by the Fourier transform. The spectrum is of particular interest when pulses are subject to signal processing. For example, when a chirp pulse is compressed by its matched filter, the resulting waveform contains not only a main narrow pulse but, also, a variety of unwanted artifacts many of which are directly attributable to features in the chirp's spectral characteristics. The simplest way to derive the spectrum of a chirp, now computers are widely available, is to sample the time-domain waveform at a frequency well above the Nyquist limit and call up an FFT algorithm to obtain the desired result. As this approach was not an option for the early designers, they resorted to analytic analysis, where possible, or to graphical or approximation methods, otherwise. These early methods still remain helpful, however, as they give additional insight into the behavior and properties of chirps.