βECET 310 DEVRY Course Tutorial/Uoptutorial
ECET 310 Entire Course
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ECET 310 Week 1 Homework 1_1
ECET 310 Week 1 Homework 1_2
ECET 310 Week 2 Assignment Homework 2_1
ECET 310 Week 2 Assignment Homework 2_3
ECET 310 Week 3 Assignment Homework 3_1
ECET 310 Week 3 Assignment Homework 3_2
ECET 310 Week 5 Assignment Homework 5_1
ECET 310 Week 7 Homework 7_1
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ECET 310 Week 1 Homework 1_1
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ECET 310 Week 1 Homework 1_1
Computer ScienceβββGeneral Computer Science
1. Add:
(a) 60 dB + 25 dB=
(b) 20 dBW + 5 dBW=
(c) 22 dBβββ4 dB=
2. Convert:
(a) 65 W into dB =
(b) 10 dB into watts
(c)βββ5 dB into watts=Β .
(d) β30 dBm into dBrn =
(e) 15 dBrn into dBm =
2. A three-stage amplifier is shown with power gains. Calculate total power gain in decibels, and as a number
3. (a) Determine the overall power gain.
b) Find the output power if Pin = 15 mW
4. If Pin = -20 dBm, determine the output power in dBm and watts
5. Determine:
Net gain (b) Net gain in dBs (c) Power output
6. Determine:
(a) Net gain (b) Net gain in dBs (c) Power output
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ECET 310 Week 1 Homework 1_2
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1Β . Four frequencies are applied at the input of a non-linear amplifier. Write down all of the frequency components at the output of the non-linear device. Write down only the first three harmonics.
2. Find out the frequency components at the output of a resonant-tuned circuit tuned at 1200 KHz with a bandwidth of 15 KHz and connected at the output of a non-linear amplifier (mixer).
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ECET 310 Week 2 Assignment Homework 2_1
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1. Assume that a receiver has a first amplifier stage with a 5KW input resistance, a gain of 300, an input audio signal of 20 mV, and an operating temperature of 27oC. When the amplifier is operating with a bandwidth first of 10 MHz, find
(a) therms input noise levels
(b) the audio output levels
the rms output noise levels
2. We have an amplifier with a 1 MHz bandwidth and a 20 mV input signal. The input mV, output mV, and output mV.
Find
(a) SNR at the input
(b) SNR at the output
Noise figure
3. An FM receiver has at the input and at the output.
Calculate the receiverβs noise figure in dBβs.
4. A 300 W resistor is connected across the 300 W antenna input of a television receiver. The bandwidth of the receiver is 6 MHz, and the resistor is at room temperature (20oC). Find the noise power and noise voltage applied to the receiver input.
5. The signal at the input of an amplifier has an SNR of 42 dB. If the amplifier has a noise figure of 6 db, what is the SNR at the output (in dBβs)Β ?
6. A three-stage amplifier is shown. The operating bandwidth is 500 KHz at a temperature of 25o C. The output load is 1000W.
7. The noise input power is 1 pW/Hz. Determine the output noise power.
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ECET 310 Week 2 Assignment Homework 2_3
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1. The bandwidth of a series resonant circuit is 400 Hz.
(a) If the resonant frequency is 4000 Hz, find Q.
(b) If Ξ©, what is the value of XL at resonance?
Find the inductance L and capacitance C of the circuit.=
2. The frequency response curve for an RLC circuit is shown in the diagram.
(a) Determine Q and bandwidth for the frequency response curve shown.
(b) For ΞΌF, determine L and R for the resonant circuit.
Determine the applied voltage.
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ECET 310 Week 3 Assignment Homework 3_2
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1. Draw the frequency spectrum at the output of the first balanced modulator.
2. If the filter is a low pass filter, draw the frequency spectrum at the output of the filter and amplifier
3. Draw the frequency spectrum at the output of the second balanced modulator.
4. If the filter is a low pass filter, draw the frequency spectrum at the output of the filter and linear power amplifier.
5. Find the value for the required Q for the first filter.
6. Find the value for the required Q for the second filter.
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ECET 310 Week 3 Assignment Homework 3_1
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1. An AM signal has an unmodulated carrier voltage VC = 10VP, a load resistance of RL = 10, and a modulation index of m = 1. Determine:
Modulation
(a) PC = Vc2/2/2(10)=
PSB =PT-PC/2=
(b) Total power in the AM signal
2. Find the modulation index corresponding to the given trapezoidal pattern for the AM signal.
3. You are tuned to an AM station at 1200 KHz. Write down the frequency components of the received AM signal.
4. Draw an AM signal for the given conditions:
(a)
b) m>1
c)m<1
5. An AM transmitter is transmitting at 1000 W. If the modulation index is 0.9 and antenna impedance is 50 ohms, find:
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ECET 310 Week 5 Assignment Homework 5_1
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1. Determine the Nyquist sample rate for a maximum analog input frequency of:
(a) 4 KHz
10 KHz
2. Determine the dynamic range for a 10-bit sign-magnitude PCM code.
3. Determine the minimum number of bits required in a PCM code for a dynamic range of 80 dB. What is the coding efficiency?
4. For a resolution of 0.04 V, determine the voltages for the following linear seven- bit sign magnitude PCM codes
5. Determine the resolution and quantization error for an eight-bit linear sign magnitude PCM code for a maximum decoded voltage of 1.27 V
6. For a 12-bit linear PCM code with a resolution of 0.02 V, determine the voltage range that would be converted to the following PCM codes.
7. A Β΅-law compression encoder has
ECET 310 Week 6 Assignment Homework 6_1
Computer ScienceβββGeneral Computer Science
1. For a 64-PSK modulator with an input data rate(fb) equal to 36 Mbps and a carrier frequency of 100 MHz, determine the minimum double-sided Nyquist bandwidth(fN) and the baud. Sketch the output spectrum.
2. Determine the bandwidth efficiency for the following modulators:
(a) QPSK =
(b) 64-QPSK =
(c) 128-QAM=
3. A radio channel has a bandwidth of 10 KHz and a SNR of 15 dB. What is the maximum data rate that can be transmitted:
a) Using any system?
b) Using a code with 64 possible states?
4. A modulator transmits symbols, each of which has 64 different possible states, 15,000 times per second. Calculate the baud rate and the bit rate
5. What is the shannon limit for a standard telephone circuit with an SNR of 30 dB and a bandwidth of 3.3 KHz?
6. What is the maximum data rate possible for a standard telephone circuit with an SNR of 1023 and BW of 3 KHz using 8 bits per symbol?
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ECET 310 Week 7 Homework 7_1
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1. For a QPSK system and the given parameters, determine
2. Which system requires the highest Eb/No ratio for a probability of error of 10β7, four-level QAM or 8-PSK system?
3. Determine the minimum bandwidth required to achieve a P(e) of 10β4 for a 16-PSK system operating at 25 Mbps with a carrier-to-noise ratio of 10 dB
4. A PCM-TDM system multiplexes 32 voice channels each with a bandwidth of 0 Khz to 4 KHz. Each sample is encoded with an 8-bit PCM code. UPNRZ encoding is used. Determine:
5. Consider a PCM-TDM system in which 24 signals are to be processed. Each signal has a baseband bandwidth of 3 KHz. The sampling rate has to be 33.3% higher than the theoretical minimum, and 8 bits are to be used. Conventional NRZ-L encoding format is used. An extra bit is added to each frame for sync. Determine
