Exp03_vS1 - Electrical and Computer Engineering
... 6. Increase the function generator frequency to 5 kHz. Use the horizontal control on the oscilloscope to view only two periods of the new signal. 7. Increase the DC offset to 2 V on the function generator. On the oscilloscope, change the coupling mode to DC. How is the signal different now, and how ...
... 6. Increase the function generator frequency to 5 kHz. Use the horizontal control on the oscilloscope to view only two periods of the new signal. 7. Increase the DC offset to 2 V on the function generator. On the oscilloscope, change the coupling mode to DC. How is the signal different now, and how ...
3 - Dynamic Learning
... No, can Grouped only estimate Bothyou opinions gave part of the the range. correct This is used where there are many answer. possible values for the data. It is aonly We do not the exact data values, convenient way handling large which groupclass theyofisare in. The modal ...
... No, can Grouped only estimate Bothyou opinions gave part of the the range. correct This is used where there are many answer. possible values for the data. It is aonly We do not the exact data values, convenient way handling large which groupclass theyofisare in. The modal ...
Efficiency of AM modulation
... pulses to a tank (resonant) circuit. Each pulse initiates a damped oscillation in the tuned circuit. The oscillation would have an initial amplitude proportional to the size of the current pulse and decay rate dependent on the time constant of the circuit. Since a train of pulses is fed to the ...
... pulses to a tank (resonant) circuit. Each pulse initiates a damped oscillation in the tuned circuit. The oscillation would have an initial amplitude proportional to the size of the current pulse and decay rate dependent on the time constant of the circuit. Since a train of pulses is fed to the ...
California Instruments CS series current source
... square waveforms in addition to user defined arbitrary waveforms. Harmonic waveforms can be used to test for harmonic current susceptibility of a unit under test. With the help of the supplied ...
... square waveforms in addition to user defined arbitrary waveforms. Harmonic waveforms can be used to test for harmonic current susceptibility of a unit under test. With the help of the supplied ...
CHAPTER 5: SYSTEM INTEGRATION
... Figure 5.19 shows the modified eye diagram for the system if no noise or fading is present. Figure 5.20 shows the modified eye diagram if only fading with variance 0.25 and sampling time of 80 ns is specified. Figure 5.21 shows the modified eye diagram if the noise of variance 1 is added and sampled ...
... Figure 5.19 shows the modified eye diagram for the system if no noise or fading is present. Figure 5.20 shows the modified eye diagram if only fading with variance 0.25 and sampling time of 80 ns is specified. Figure 5.21 shows the modified eye diagram if the noise of variance 1 is added and sampled ...
Chapter 2-AMSC
... There are cases where the interharmonic components are produced by the picket-fence effect when applying the FFT, due to sampling the signal with a spectral leakage. The picketfence effect occurs when the analyzed waveform includes spectral components which are not an integer multiple of the FFT fun ...
... There are cases where the interharmonic components are produced by the picket-fence effect when applying the FFT, due to sampling the signal with a spectral leakage. The picketfence effect occurs when the analyzed waveform includes spectral components which are not an integer multiple of the FFT fun ...
Chapter 4 Amplitude Modulations and Demodulations
... • Transmitting the carrier with the modulated signal leads to so-called AM in which the transmitted signal is given as: • The spectrum is the same as the DSB-SC (m(t) cos ωct) except for two additional impulses ±fc • Comparing φAM(t) and φDSB-SC (t) = m(t) cos ωct, Am signal is identical to the DSB- ...
... • Transmitting the carrier with the modulated signal leads to so-called AM in which the transmitted signal is given as: • The spectrum is the same as the DSB-SC (m(t) cos ωct) except for two additional impulses ±fc • Comparing φAM(t) and φDSB-SC (t) = m(t) cos ωct, Am signal is identical to the DSB- ...
BE1-GPS Product Screenshow
... • User defined variable names – Easier to analyze event reports – Allows virtual switch name to be customized to application ...
... • User defined variable names – Easier to analyze event reports – Allows virtual switch name to be customized to application ...
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.