E2.3 Given a two-input neuron with the following weight matrix and input vector:w=[32] and p = [-5 7], we would like to have an output of 0.5. Do yousuppose that there is a combination of bias and transfer function that might allowthis?i. Is there a transfer function from Table 2.1 that will do the job if the bias is zero?ii. Is there a bias that will do the job if the linear transfer function is used? If yes,what is it?iii. Is there a bias that will do the job if a log-sigmoid transfer function is used?Again, if yes, what is it?iv. Is there a bias that will do the job if a symmetrical hard limit transfer function isused? Again, if yes, what is it?

Answered: Image /qna-images/answer/682e706a-f9db-4064-b346-f38f5e4ce9e9.jpg

Answered: E2.3 Given a two-input neuron with the…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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E2.2 Consider a single-input neuron with a bias. We would like the output to be -1 for inputs less than 3 and +1 for inputs greater than or equal to 3. i. What kind of a transfer function is required? ii. What bias would you suggest? Is your bias in any way related to the input weight? If yes, how? iii. Summarize your network by naming the transfer function and stating the bias and the weight. Draw a diagram of the network.
Circuit1( 4 mosfets) Cicruit2( 2 mosfets) The gain of the circuit 1 is -gm1(Ron ll Rop) and the gain of circuit 2 is -Gm(ro1 ll ro2) Combine the gain of these two circuits (drawing the small signal model could help)
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Q_. A simple comparator and a Schmitt trigger are shown in Figures 2(a) and _(b). The maximum output voltage, Vmax, can switch between -10 V and ! 10 V for both circuits. The lower and upper trigger levels of the Schmitt trigger are -1 V and 12 V, respectively. a) b) Based on the information given above, sketch the transfer characteristics for both circuits. +2V Show that the hysteresis of the Schmitt trigger of Figure 2(b) can be expressed as c) Using the parameters provided above, determine the ratio of R₂/R₁ for the circuit of Figure 2(b). 1₂ Vhys = Figure 2(a) 2.R₁-Vmax R₁ + R₂ V₂ KŲ +0.6V R₂ Figure 2(b) Tºv.
Output voltage, V, of a microphone is a Gaussian random variable with a mean of OV and variance of 2.8V2. Microphone output is processed by a limiting rectifier with cutoff at OV and +4.2V. (Output below OV is clipped to OV, and output above 4.2 V is clipped to 4.2V.) Random variable L is the output of the limiter: a. What is the CDF of L? b. What is the PDF of L? c. What is the E[L]? 0 L = g(V) = {V 4.2 V 4.2
Q) Input signals are given as V1 = 3sin(wt) V2 = 2sin(wt) V3 = 1sin(wt) in circuit. a) Find equation that expresses output signal in terms of input signals. B) Write sinuzoidal expression of output signal.
Construct the Signal Flow Graph for the block diagram shown in Figure 1 below. G5 GI G2 G3 G4 H2 H3 Figure 1 : Block diagram for Assignment 1
y4 Consider the Signal Flow Graph in the figure below and find the transfer function: yl -H2 y2 G1 y4 G2 G3 -G4 -H1 G1(G2-G4) 1+G2G3H2+G1G2H1–G3G4H2–G1G4H1 a) b) y4 G1 1+G2G3H2+G2H1-G3G4H2-G1G4H1 yl y4 yl c) GIG4 1+G2H2+G1G2–G3G4H2 GIG4H1 y4 G2(G1-G4) y1 1+G2G3H2+G1G2H1-G2G4H2–G1G4H1 y4 G1(G2-G3) e) yl G3H2+G1G2H1-G3G4H2–G1G4H1 G1(G3-G4) 1+G2G3H2+G1G3G4H1-G3G4H2–G1G2H1 yl y4 yl GIG3H2 1+G2G3H1+GIG2H1-G4H1 g) h) 1+G2H2+G1G2H1–G4H2–G1G4 y4 G1(G2-G4) yl 1+G3H2+G1G3H2-G3G4H2-G1G2H1 y4 GIG? 1+G2G3+G2H1-G3G4H2-G1G4H1 yl
B6
Prob 1: For each of the 8 circuits below, draw small signal model and calculate Vout/Vin. Vh1 Vh2 are dc voltage sources, and Il is an ideal dc current source. Ignore body effect for all problems. Vino- M3H M₂ VDD (a) →Vb3 Vb2 Vout M₁ →Vb1 J HE VDD M3 (b) - Vout VinM₂ 4M₁ J VDD M3 VinM₂ 4M₁ (c) Vout
Number 22
Fundamentals of Mixed Signals and Sensors Topic: ADC DAC Solve for the output of the DAC in figure below if the waveforms representing a sequence of 4-bit numbers in figure below are applied to the inputs. Input D0 is the least significant bit (LSB). Reverse the input waveforms to the DAC in the figure (D3 to D0, D2 to D1, D1 to D2, D0 to D3) and determine the output.

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