Simulation of Silicon Photomultiplier Signals
... 3f42. In a first simulation aimed at the direct comparison of simulated and measured pulse traces, a transient analysis was performed on the circuit shown in Fig. 2. This circuit consists of the SiPM model discussed in Section II-A, a shunt resistor , and a preamplification stage. The values of the ...
... 3f42. In a first simulation aimed at the direct comparison of simulated and measured pulse traces, a transient analysis was performed on the circuit shown in Fig. 2. This circuit consists of the SiPM model discussed in Section II-A, a shunt resistor , and a preamplification stage. The values of the ...
Formula for two-carrier intermodulation distortion
... equivalent results obtained by numerical solution of (1)–(3) are also depicted, showing, as expected, excellent agreement. As it can be appreciated, both harmonic and intermodulation distortions show lowpass characteristics, however, with different roll-off frequencies than the linear normalized tra ...
... equivalent results obtained by numerical solution of (1)–(3) are also depicted, showing, as expected, excellent agreement. As it can be appreciated, both harmonic and intermodulation distortions show lowpass characteristics, however, with different roll-off frequencies than the linear normalized tra ...
Receiver2
... Advantages Weak signals are not attenuated Disadvantages Complex than simple AGC ...
... Advantages Weak signals are not attenuated Disadvantages Complex than simple AGC ...
Chapter 2 (Part 1)
... For an AM DSCFC wave with a peak unmodulated carrier voltage Ec = 10 Vp, a load resistor of RL = 10 and m = 1, determine a) Powers of the carrier and the upper and lower sidebands. b) Total sideband power. c) Total power of the modulated wave. d) Draw the power spectrum. ...
... For an AM DSCFC wave with a peak unmodulated carrier voltage Ec = 10 Vp, a load resistor of RL = 10 and m = 1, determine a) Powers of the carrier and the upper and lower sidebands. b) Total sideband power. c) Total power of the modulated wave. d) Draw the power spectrum. ...
ppt
... the muscle decreases and the muscle, skin and electrodes will be moving with respect to each other. The electrode signal will therefore probably show some movement artifacts. This is not the only difficulty when measuring an EMG. When the muscle is moving, the body will show some movements as well ...
... the muscle decreases and the muscle, skin and electrodes will be moving with respect to each other. The electrode signal will therefore probably show some movement artifacts. This is not the only difficulty when measuring an EMG. When the muscle is moving, the body will show some movements as well ...
Wireless Communications and Networks
... Long haul telecommunications service Short point-to-point links between buildings ...
... Long haul telecommunications service Short point-to-point links between buildings ...
HYPERLYNX A PWB DESIGN TOOL
... along with easy models May need to obtain IBIS models from vendors Repeat for all other drivers/receivers on net ...
... along with easy models May need to obtain IBIS models from vendors Repeat for all other drivers/receivers on net ...
m4.4 Signal Processing Circuits: (a) Design a two
... guitar. The first-stage amplifier applies a variable gain magnitude in the range 13.3 to 23.3 while the second-stage amplifier attenuates the signal by 13.3, i.e., the second-stage amplifier has a fixed gain of 1/13.3. Note that when the first-stage amplifier gain is 13.3 the overall distortion box ...
... guitar. The first-stage amplifier applies a variable gain magnitude in the range 13.3 to 23.3 while the second-stage amplifier attenuates the signal by 13.3, i.e., the second-stage amplifier has a fixed gain of 1/13.3. Note that when the first-stage amplifier gain is 13.3 the overall distortion box ...
iTOP_carrier_amplifier_studies_at_IU
... SPICE, although IRSX results suggest it will be a further 22% lower. The 10% discrepancy is explained: prototype circuit didn’t exactly match carrier rev E / SPICE circuit. Was effectively a 100 Ω / 1 kΩ voltage divider at the input, owing to bias resistor connection. Changed this now to match car ...
... SPICE, although IRSX results suggest it will be a further 22% lower. The 10% discrepancy is explained: prototype circuit didn’t exactly match carrier rev E / SPICE circuit. Was effectively a 100 Ω / 1 kΩ voltage divider at the input, owing to bias resistor connection. Changed this now to match car ...
Sampling Bounds for Sparse Support Recovery in the Presence of
... rate per sample is needed. In this paper, it is shown that an unbounded SNR is also a necessary condition for perfect recovery, but any fraction (less than one) of the support can be recovered with bounded SNR. This means that a finite rate per sample is sufficient for partial support recovery. Nece ...
... rate per sample is needed. In this paper, it is shown that an unbounded SNR is also a necessary condition for perfect recovery, but any fraction (less than one) of the support can be recovered with bounded SNR. This means that a finite rate per sample is sufficient for partial support recovery. Nece ...
PULSE MODULATION
... Noise interference at the top of transmitted pulse can be easily removed. Due to this it is widely used. ...
... Noise interference at the top of transmitted pulse can be easily removed. Due to this it is widely used. ...
Statistical Estimation of Error Probability in a Digital Wireless
... assumed that the phase is constant within the signal interval [0, T], an assumption which is valid for the digital modulation type: FSK, QPSK and QAM. Different statistical distributions are used to estimate the received signal level under fading conditions. In [2], the multipath fading environment ...
... assumed that the phase is constant within the signal interval [0, T], an assumption which is valid for the digital modulation type: FSK, QPSK and QAM. Different statistical distributions are used to estimate the received signal level under fading conditions. In [2], the multipath fading environment ...
Signal Corps (United States Army)
The United States Army Signal Corps develops, tests, provides, and manages communications and information systems support for the command and control of combined arms forces. It was established in 1860, the brainchild of United States Army Major Albert J. Myer, and has had an important role from the American Civil War through to the current day. Over its history, it had the initial responsibility for a number of functions and new technologies that are currently managed by other organizations, including military intelligence, weather forecasting, and aviation.