ECET 350 Knowledge is divine / snaptutorial.com

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ECET 350 Knowledge is divine / snaptutorial.com
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 2 Homework For more classes
visit www.snaptutorial.com   Chapter 2, page
58-62, problems 2a, 2b, 2c, 7, 9a, 9b, 9c, 10a,
10b, 16a, 16b, 16c, 19, 21, 22a, 22b, 22c, 24.  
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 2 iLab Signal Sampling and
Reconstruction For more classes
visit www.snaptutorial.com   Objectives Use
principles of signal sampling and reconstruction
to construct an electronic
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 3 Homework For more classes
visit www.snaptutorial.com   Chapter 3 Homework
Problems 3a, 3b, 3c, 5a, 5c, 5e, 7a, 9
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 3 iLab Moving Average Digital
Filters For more classes visit www.snaptutorial.
com   Objectives Design, test, and implement
antialiasing and anti-imaging filters to be used
with a real-time, digital filtering system using
a microcontroller, ADC, and DAC. Implement, test,
and analyze the performance of a moving average,
low-pass filter in conjunction with the filters
and real-time system from the first objective.
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 4 Homework For more classes
visit www.snaptutorial.com   Chapter 9 Finite
Impulse Response Filters, pp. 314353 Problems
2a, 2b, 2c, 2d, 3a, 3b, 8a, 8b, 8c, 8d, 8e, 8f,
10b, 11b, 12b, 12d, 14a, 14b
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 4 iLab Low-Pass Finite Impulse
Response Filter For more classes
visit www.snaptutorial.com   Objectives Design,
implement, test, and analyze the performance of a
finite impulse response, low-pass filter in a
real-time application using the Tower
microcontroller board and ADC and DAC interface
board.  
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 5 Homework For more classes
visit www.snaptutorial.com   Chapter 9 19.
Design a low pass FIR filter for a 10 kHz
sampling, with a pass band edge at 2 kHz, a stop
band edge at 3 kHz, and 20 dB stop band
attenuation. Find the impulse response and the
difference equation for the filter.
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 5 iLab Impulse Response Band Pass
Filter For more classes visit www.snaptutorial.c
om   Objectives Design a high-order, FIR band
pass using MATLAB and then to implement, test,
and analyze the real-time performance of that
filter on a target embedded system board. In
addition, introduce and compare the numerical
formats and
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 6 Homework For more classes
visit www.snaptutorial.com   Chapter 10 Homework
Problems 12a, 12b
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 6 iLab Infinite Impulse Response
Low-Pass Filter For more classes
visit www.snaptutorial.com   Objectives Design a
Butterworth, low-pass filter, and then, using a
bilinear transformation operation, create a
digital IIR filter. The filter will then be
implemented and real-time performance tested and
analyzed on a target embedded system
board. Results Summarize your results in the
context of your objectives.
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 7 Homework For more classes
visit www.snaptutorial.com   ECET 350 Practice
Problems 1. A first-order Butterworth filter with
a digital cut-off frequency of p/4 radians is
designed for a 2 kHz sampled system. The
pre-warped analog transfer function is
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 7 iLab Fourier Analysis of Time
Domain Signals For more classes
visit www.snaptutorial.com   Objective of the lab
experiment The objective of this experiment is
to perform Fourier analysis to obtain frequency
domain signature of signals and systems that are
measured or whose characteristics are known in
time domain. Towards this end, we shall learn how
to use Fourier
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ECET 350 Knowledge is divine / snaptutorial.com
ECET 350 Week 7 Homework For more classes
visit www.snaptutorial.com   ECET 350 Practice
Problems 1. A first-order Butterworth filter with
a digital cut-off frequency of p/4 radians is
designed for a 2 kHz sampled system. The
pre-warped analog transfer function is 2. The
transfer function of an analog filter is H(s)
5000/(s 15000). If the sampling frequency is 20
kHz, the digital filter obtained using the
bilinear transformation is
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ECET 350 Knowledge is divine / snaptutorial.com