Fall 2018 Exam1 BME3500 Biomeasurements 4. A second order low-pass RC filter is made by cascading...
C, V. Low-pass High-pass Procedure: Design the following filters and be certain to provide the component values you used in a table like those shown on the third page. Record your calculations because they will be requested in the lab report. To make the lab simpler let the input resistor Ri be the same for all stages. In this particular case the loading effects from cascading the op-amp circuits will have little influence on the overall gain. Refer to your...
Determine the transfer function for a 2nd order Chebyshev low pass filter with 3dB frequency of 100krad/sec, a maximum gain of OdB, and a passband ripple of 1dB. (40 points) (a) (b) A bandpass filter is made by cascading the filter described in part (a) with a 2nd order Chebyshev high pass filter with 3dB frequency of 1krad/sec, a maximum gain of OdB and passband ripple of 2dB. Determine the midband gain of the filter. (30 points) A Chebyshev bandpass...
Active Low-pass and High-pass Filters for Crossover Circuitry (PSPICE) Design a first order active high-pass filter with cut-off frequency of 1 kHz & gain 20dB. Design a first order active low-pass filter with cut-off frequency of 1 kHz & gain 20dB. Plot the magnitude and phase responses of the active high-pass and low-pass filters you have designed using PSpice (Use UA741 Op amp and ±12V dual supply). Connect your active low-pass and high-pass filters as shown in Fig. 1-b. Assume...
200 HZ. 6.25) Design a cascading LC low-pass filter with maxi- mally flat magnitude response. Use a passband of 0 to 5 kHz with 5 kHz cutoff frequency and filter to attenuate all frequencies at and above 10 kHz by at least 30 dB. Use R R1 = 50 2 200 HZ. 6.25) Design a cascading LC low-pass filter with maxi- mally flat magnitude response. Use a passband of 0 to 5 kHz with 5 kHz cutoff frequency and filter...
1. By using an analog filter with a Butterworth response of order 3, design a digital IIR low pass filter with 3-db cutoff frequency 2c 0.6TT a) b) c) Evaluate the transfer function of the analog filter (10marks) Skecth the block diagram of transfer function (5 marks) Plot the magnitude response of the filters. (5marks) 1. By using an analog filter with a Butterworth response of order 3, design a digital IIR low pass filter with 3-db cutoff frequency 2c...
Using filterDesigner in MATLAB, design a second order low pass IIR Butterworth filter whose sampling frequency (Fs) is 1 kHz and cutoff frequency (Fc) is 10 Hz. Find the numerator and denominator coefficients. Write its transfer function H(z) = Y(z) / X(z). Write its difference function y(k). Draw (copy from Filter Designer) the magnitude response plot. Draw (copy from Filter Designer) the phase response plot. Draw (copy from Filter Designer) the impulse response plot.
Design a second-order Butterworth low-pass filter to satisfy the specifications a. The dc gain is unity (zero dB); b. The gain is no smaller than -1 dB for frequencies between 0 and 2,000 Hz; and c. The gain is no larger than -40 dB for frequencies larger than 40 kHz. Determine a circuit realization as a series RLC low-pass filter. Pick reasonable values of R, L, and C. Design a second-order Butterworth low-pass filter to satisfy the specifications a. The...
(a) Design a first order active low pass filter with a corner frequency of 1 kHz and a normalized transfer function of 1/(s + 1.96523). You may assume C = 10 nF.
Using filterDesigner in MATLAB, design a second order low pass IIR Butterworth filter whose sampling frequency (Fs) is 1 kHz and cutoff frequency (Fc) is 10 Hz. Find the numerator and denominator coefficients. Write its transfer function H(z) = Y(z) / X(z). Write its difference function y(k). Draw (copy from Filter Designer) the magnitude response plot. Draw (copy from Filter Designer) the phase response plot. Draw (copy from Filter Designer) the impulse response plot.
Learning Goal: To analyze and design a passive, first-order low- pass filter using a series RL circuit. The analysis and design will be repeated for a series RC circuit. An electrocardiogram needs to detect periodic signals of approximately 1 Hz (since the resting heart rate of a healthy adult is between 55 and 70 beats per minute). The instrument operates in an electrical environment that is very noisy with a frequency of 60 Hz. It is desirable to have a...