PITCH RECOGNITION
... In the case of the Oboe sound, the fundamental frequency is again 262 Hz, and is present with its harmonics; but, one can notice that the most prominent frequency component is the 4th harmonic. What may not be obvious is that to the human ear this sound will be heard as having the same pitch as sinu ...
... In the case of the Oboe sound, the fundamental frequency is again 262 Hz, and is present with its harmonics; but, one can notice that the most prominent frequency component is the 4th harmonic. What may not be obvious is that to the human ear this sound will be heard as having the same pitch as sinu ...
![Ask the Applications Engineer—30 by Adrian Fox [] PLL SYNTHESIZERS](http://s1.studyres.com/store/data/000068689_1-dc1ef7b58d77ba17e07788048243a0eb-300x300.png)
W-band push–push monolithic frequency doubler in 1
... at the vicinity of 7 dBm for input power, the output power began increasing rapidly and the fundamental wave came into compression. This indicates that the doubler was driven effectively and nonlinearity was strengthened. Hence the second harmonic frequency was triggered out. When the input signal r ...
... at the vicinity of 7 dBm for input power, the output power began increasing rapidly and the fundamental wave came into compression. This indicates that the doubler was driven effectively and nonlinearity was strengthened. Hence the second harmonic frequency was triggered out. When the input signal r ...
AN1229
... Typical input gate-to-gate impedance of SD2932 at 100 MHz is Zin = Rs + jXs = 2 - 2.6 j, and can also be expressed as the combination of parallel resistance and reactance using the following formulas: Equation 1 Xs Rp = Rs • 1 + ⎛ -------⎞ ⎝ Rs⎠ ...
... Typical input gate-to-gate impedance of SD2932 at 100 MHz is Zin = Rs + jXs = 2 - 2.6 j, and can also be expressed as the combination of parallel resistance and reactance using the following formulas: Equation 1 Xs Rp = Rs • 1 + ⎛ -------⎞ ⎝ Rs⎠ ...
EL5102, EL5103, EL5202, EL5203, EL5302
... All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems. Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes ...
... All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems. Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes ...
A 5.9-GHz Voltage-Controlled Ring Oscillator in 0.18
... be compensated by using a larger excess noise factor in the equations. Fig. 4(b) shows the measured power spectrum at the divide-by-two output of the nine-stage design. The phase noise of the nine-stage design was extracted as 105.5 dBc/Hz at a 1-MHz offset from a 1.81-GHz center frequency; this val ...
... be compensated by using a larger excess noise factor in the equations. Fig. 4(b) shows the measured power spectrum at the divide-by-two output of the nine-stage design. The phase noise of the nine-stage design was extracted as 105.5 dBc/Hz at a 1-MHz offset from a 1.81-GHz center frequency; this val ...
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.