K Maps and Truth Tables-Basic Unified Engineering-Assignment, Exercises of Engineering

Prof. Uddhar Negi gave this assignment for Advanced Unified Engineering course at Allahabad University. It includes: Karnaugh, Maps, Truth, Tables, Simplify, Expression, Boolean, Diagram, Convert, Rules, Engine

Typology: Exercises

2011/2012

Uploaded on 07/22/2012

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C16
The problems in this problem set cover lecture C16
1.
a. Using truth tables, show that )( BABA +=
b. Using K-Maps, simplify the following expression:
CBACBACBACBA +++
c. Using K-Maps, simplify the following expression:
DCDCBADCBDBA +++
d. Simplify the same expression using the rules of simplification (Boolean
Algebra Theorems).
Note: When using truth tables, list the complete table.
When using K-Maps, show the simplifications on the diagram.
When using rules of simplification, state the rule being used on the same line in
square brackets.
2. Convert the following expression into product of sum form:
CBACBACBACBA +++
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C

The problems in this problem set cover lecture C

a. Using truth tables, show that AB =( A + B )

b. Using K-Maps, simplify the following expression:

A 〈 B 〈 C + A 〈 B 〈 C + A 〈 B 〈 C + A 〈 B 〈 C

c. Using K-Maps, simplify the following expression: ABD + BCD + ABCD + CD

d. Simplify the same expression using the rules of simplification (Boolean Algebra Theorems).

Note : When using truth tables, list the complete table. When using K-Maps, show the simplifications on the diagram. When using rules of simplification, state the rule being used on the same line in square brackets.

  1. Convert the following expression into product of sum form:

A 〈 B 〈 C + A 〈 B 〈 C + A 〈 B 〈 C + A 〈 B 〈 C

Unified Engineering Spring Term 2004

Problem P8. (Propulsion) (L.O. G)

To answer this question, it will be necessary to make some

estimates from the CFM56-003 engine.

Measure the inlet and exit blade angles near the root of the fan and

the inlet blade angle of the first stator blade on the 3-stage low

pressure compressor (the "booster" as labeled above).

a) Based on these measurements and assuming that the axial flow

Mach number is 0.5, how fast does the low-speed/low pressure

spool rotate? Please give your answer in RPM's (revolutions per

minute). Make two estimates, one based on the flow angle into the

fan and one based on the flow angle into the stator.

Image removed due to copyright considerations.

Unified Engineering Spring Term 2004

Problem P9. (Propulsion) (L.O. G)

Consider the turbine rotor shown below. The velocity (V 1 ) and

absolute frame flow angle (β 1 ) entering the rotor are fixed. The

flow angle leaving the rotor in the relative frame (β2’) is also fixed.

Further, β 1 = β2’. The rotor speed (rω) can be changed by varying

the load on the shaft. Assume the axial velocity (w) entering and

exiting the blade row is the same.

a) Draw velocity triangles in the relative and absolute frames for

the different blade speeds shown below for both the inlet and exit

to the rotor. (Note the inlet velocity components form a 3-4-

triangle.)

b) For the three cases drawn in part a), which extracts the most

power from the flow and why?

c) If you were asked to design for maximum power extraction and

could choose any blade speed between 0 and rω = 2w, what speed

would you choose?

You can argue this either graphically or with reference to the Euler

Turbine Equation:

d) For what rotational speed does the "turbine" in this example,

begin to act like a compressor? What might you expect the

aerodynamic performance to be for the blades in such a situation -

good or bad, and why?

Unified Engineering II Spring 2004

Problem S15 (Signals and Systems)

Find the Fourier transforms of the following signals:

g(t) = δ(t − T ) Note: The system with impulse response g(t) produces an output that is the input delayed by T. Since delays occur frequently in signal processing, G(jω) is an important transfer function.

g(t) =

1 , |t| ≤ T 0 , |t| > T

Note: Because g(t) is symmetric, G(jω) should be real. Please express your answer so that it is apparent that the answer is real.

g(t) =

t^2 + T 2 Hint: If you find the integral hard to do, you might be able to find the answer using duality.

g(t) =

sin πt/T πt/T Hint: You almost certainly won’t be able to do the FT integral directly. Use duality and the results of (2) above to find the answer. The g(t) in this problem has important connections to, among other things, CD players!

  1. Find the inverse transform of

G(jω) =

sin ωT ωT

using the results of part (2), and FT properties.