(a) Plot the signal sent if Manchester Encoding is usedIf Manchester Encoding is used, the encoding for a binary one is a high voltage for the first half of the bit period and a low voltage for the second half of the bit period. For the binary zero, the reverse is true.
The bit sequence is 0011001010, so the signal sent using Manchester encoding is shown below: (b) Plot the signal sent if Differential Encoding is used.If differential encoding is used, the first bit is modulated by transmitting a pulse in the initial interval.
To transfer the second and future bits, the phase of the pulse is changed if the bit is 0 and kept the same if the bit is 1. The bit sequence is 0011001010, so the signal sent using differential encoding is shown below: (c) Data rate for both (a) and (b) is as follows:
Manchester EncodingThe signal is transmitted at a rate of 1 bit per bit interval. The bit period is the amount of time it takes to transmit one bit. The signal is repeated for each bit in the bit sequence in Manchester Encoding. The data rate is equal to the bit rate, which is 1 bit per bit interval.Differential EncodingThe signal is transmitted at a rate of 1 bit per bit interval.
The bit period is the amount of time it takes to transmit one bit. The signal is repeated for each bit in the bit sequence in Differential Encoding. The data rate is equal to the bit rate, which is 1 bit per bit interval.
(d)Comparison between the two encodings:
Manchester encoding and differential encoding differ in several ways. Manchester encoding has a higher data rate but a greater DC offset than differential encoding. Differential encoding, on the other hand, has a lower data rate but a smaller DC offset than Manchester encoding.
Differential encoding is simpler to apply than Manchester encoding, which involves changing the pulse's voltage level.
However, Manchester encoding is more reliable than differential encoding because it has no DC component, which can cause errors during transmission. Differential encoding is also less prone to noise than Manchester encoding, which is more susceptible to noise because it uses a narrow pulse.
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Explain briefly the advantages" and "disadvantages of the "Non ferrous metals and alloys" in comparison with the "Ferrous alloys (15p). Explain briefly the compositions and the application areas of the "Brasses"
The advantages are : 1. Non-ferrous metals are generally more corrosion resistant than ferrous alloys. 2. They are also more lightweight and have a higher melting point. 3. Some non-ferrous metals, such as copper, are excellent conductors of electricity. The disadvantages are : 1. Non-ferrous metals are typically more expensive than ferrous alloys. 2. They are also more difficult to machine and weld. 3. Some non-ferrous metals, such as lead, are toxic.
Here is a brief explanation of the compositions and application areas of brasses:
1. Brasses are copper-based alloys that contain zinc.
2. The amount of zinc in a brass can vary, and this can affect the properties of the alloy.
3. For example, brasses with a high zinc content are more ductile and machinable, while brasses with a low zinc content are more resistant to corrosion.
4. Brasses are used in a wide variety of applications, including:
Electrical connectors
Plumbing fixtures
Musical instruments
Jewelry
Coins
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Question 5 (15 marks)
For an assembly manufactured at your organization, a
flywheel is retained on a shaft by six bolts, which are each
tightened to a specified torque of 90 Nem x 10/N-m,
‘The results from a major 5000 bolt study show a normal
distribution, with a mean torque reading of 83.90 N-m, and a
standard deviation of 1.41 Nm.
2. Estimate the %age of bolts that have torques BELOW the minimum 80 N-m torque. (3)
b. Foragiven assembly, what is the probabilty of there being any bolt(s) below 80 N-m? (3)
¢. Foragiven assembly, what isthe probability of zero bolts below 80 N-m? (2)
Question 5 (continued)
4. These flywheel assemblies are shipped to garages, service centres, and dealerships across the
region, in batches of 15 assemblies.
What isthe likelihood of ONE OR MORE ofthe 15 assemblies having bolts below the 80 N-m
lower specification limit? (3 marks)
. Whats probability n df the torque is "loosened up", iterally toa new LSL of 78 N-m? (4 marks)
The answer to the first part, The standard deviation is 1.41 N-m.
How to find?The probability distribution is given by the normal distribution formula.
z=(80-83.9)/1.41
=-2.77.
The percentage of bolts that have torques below the minimum 80 N-m torque is:
P(z < -2.77) = 0.0028
= 0.28%.
Thus, there is only 0.28% of bolts that have torques below the minimum 80 N-m torque.
b) For a given assembly, what is the probability of there being any bolt(s) below 80 N-m?
The probability of there being any bolt(s) below 80 N-m is given by:
P(X < 80)P(X < 80)
= P(Z < -2.77)
= 0.0028
= 0.28%.
Thus, there is only a 0.28% probability of having bolts below 80 N-m in a given assembly.
c) For a given assembly, what is the probability of zero bolts below 80 N-m?The probability of zero bolts below 80 N-m in a given assembly is given by:
P(X ≥ 80)P(X ≥ 80) = P(Z ≥ -2.77)
= 1 - 0.0028
= 0.9972
= 99.72%.
Thus, there is a 99.72% probability of zero bolts below 80 N-m in a given assembly.
4) What is the likelihood of ONE OR MORE of the 15 assemblies having bolts below the 80 N-m lower specification limit?
The probability of having one or more of the 15 assemblies with bolts below the 80 N-m lower specification limit is:
P(X ≥ 1) =
1 - P(X = 0)
= 1 - 0.9972¹⁵
= 0.0418
= 4.18%.
Thus, the likelihood of one or more of the 15 assemblies having bolts below the 80 N-m lower specification limit is 4.18%.
5) What is the probability of the torque being "loosened up" literally to a new LSL of 78 N-m?
The probability of the torque being loosened up to a new LSL of 78 N-m is:
P(X < 78)P(X < 78)
= P(Z < -5.74)
= 0.0000
= 0%.
Thus, the probability of the torque being "loosened up" literally to a new LSL of 78 N-m is 0%.
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The open-loop transfer function of a unit-negative-feedback system has the form of
G(s)H(s) = 1 / s(s+1).
Please determine the following transient specifications when the reference input is a unit step function:
(1) Percentage overshoot σ%;
(2) Peak time tp;
(3) 2% Settling time t.
For the given open-loop transfer function 1 / (s(s+1)), the transient specifications when the reference input is a unit step function can be determined by calculating the percentage overshoot, peak time, and 2% settling time using appropriate formulas for a second-order system.
What is the percentage overshoot?To determine the transient specifications for the given open-loop transfer function G(s)H(s) = 1 / (s(s+1)) with a unit step reference input, we need to analyze the corresponding closed-loop system.
1) Percentage overshoot (σ%):
The percentage overshoot is a measure of how much the response exceeds the final steady-state value. For a second-order system like this, the percentage overshoot can be approximated using the formula: σ% ≈ exp((-ζπ) / √(1-ζ^2)) * 100, where ζ is the damping ratio. In this case, ζ = 1 / (2√2), so substituting this value into the formula will give the percentage overshoot.
2) Peak time (tp):
The peak time is the time it takes for the response to reach its maximum value. For a second-order system, the peak time can be approximated using the formula: tp ≈ π / (ωd√(1-ζ^2)), where ωd is the undamped natural frequency. In this case, ωd = 1, so substituting this value into the formula will give the peak time.
3) 2% settling time (ts):
The settling time is the time it takes for the response to reach and stay within 2% of the final steady-state value. For a second-order system, the settling time can be approximated using the formula: ts ≈ 4 / (ζωn), where ωn is the natural frequency. In this case, ωn = 1, so substituting this value into the formula will give the 2% settling time.
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Compute the Fourier Series decomposition of a square waveform with 90% duty cycle
The Fourier series decomposition of the square waveform with a 90% duty cycle is given by: f(t) = (a0/2) + ∑[(an * cos((2πnt)/T)) + (bn * sin((2πnt)/T))]
The Fourier series decomposition for a square waveform with a 90% duty cycle:
Definition of the Square Waveform:
The square waveform with a 90% duty cycle is defined as follows:
For 0 ≤ t < T0.9 (90% of the period), the waveform is equal to +1.
For T0.9 ≤ t < T (10% of the period), the waveform is equal to -1.
Here, T represents the period of the waveform.
Fourier Series Coefficients:
The Fourier series coefficients for this waveform can be computed using the following formulas:
a0 = (1/T) ∫[0 to T] f(t) dt
an = (2/T) ∫[0 to T] f(t) cos((2πnt)/T) dt
bn = (2/T) ∫[0 to T] f(t) sin((2πnt)/T) dt
where a0, an, and bn are the Fourier coefficients.
Computation of Fourier Coefficients:
For the given square waveform with a 90% duty cycle, we have:
a0 = (1/T) ∫[0 to T] f(t) dt = 0 (since the waveform is symmetric around 0)
an = 0 for all n ≠ 0 (since the waveform is symmetric and does not have cosine terms)
bn = (2/T) ∫[0 to T] f(t) sin((2πnt)/T) dt
Computation of bn for n = 1:
We need to compute bn for n = 1 using the formula:
bn = (2/T) ∫[0 to T] f(t) sin((2πt)/T) dt
Breaking the integral into two parts (corresponding to the two regions of the waveform), we have:
bn = (2/T) [∫[0 to T0.9] sin((2πt)/T) dt - ∫[T0.9 to T] sin((2πt)/T) dt]
Evaluating the integrals, we get:
bn = (2/T) [(-T0.9/2π) cos((2πt)/T)] from 0 to T0.9 - (-T0.1/2π) cos((2πt)/T)] from T0.9 to T
bn = (2/T) [(T - T0.9)/2π - (-T0.9)/2π]
bn = (T - T0.9)/π
Fourier Series Decomposition:
The Fourier series decomposition of the square waveform with a 90% duty cycle is given by:
f(t) = (a0/2) + ∑[(an * cos((2πnt)/T)) + (bn * sin((2πnt)/T))]
However, since a0 and an are 0 for this waveform, the decomposition simplifies to:
f(t) = ∑[(bn * sin((2πnt)/T))]
For n = 1, the decomposition becomes:
f(t) = (T - T0.9)/π * sin((2πt)/T)
This represents the Fourier series decomposition of the square waveform with a 90% duty cycle, including the computation of the Fourier coefficients and the final decomposition expression for the waveform.
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b) Determine the 4-point Discrete Fourier Transform (DFT) of the below function: x(n)={ 0
1
(n=0,3)
(n=1,2)
Find the magnitude of the DFT spectrum, and sketch the result. (10 marks)
The correct answer is "The 4-point DFT of the given function is x(0)=2, x(1)=0, x(2)=0, and x(3)=0. The magnitude of the DFT spectrum is 2, 0, 0, 0. The graph of the magnitude of the DFT spectrum is as shown above."
The given function is;x(n)={ 0 1
(n=0,3)
(n=1,2)
The formula for Discrete Fourier Transform (DFT) is given by;
x(k)=∑n
=0N−1x(n)e−i2πkn/N
Where;
N is the number of sample points,
k is the frequency point,
x(n) is the discrete-time signal, and
e^(-i2πkn/N) is the complex sinusoidal component which rotates once for every N samples.
Substituting the given values in the above formula, we get the 4-point DFT as follows;
x(0) = 0+1+0+1
=2
x(1) = 0+j-0-j
=0
x(2) = 0+1-0+(-1)
= 0
x(3) = 0-j-0+j
= 0
The DFT spectrum for 4-point DFT is given as;
x(k)=∑n
=0
N−1x(n)e−i2πkn/N
So, x(0)=2,
x(1)=0,
x(2)=0, and
x(3)=0
As we know that the magnitude of a complex number x is given by
|x| = sqrt(Re(x)^2 + Im(x)^2)
So, the magnitude of the DFT spectrum is given as;
|x(0)| = |2|
= 2|
x(1)| = |0|
= 0
|x(2)| = |0|
= 0
|x(3)| = |0| = 0
Hence, the magnitude of the DFT spectrum is 2, 0, 0, 0 as we calculated above. Also, the graph of the magnitude of the DFT spectrum is as follows:
Therefore, the correct answer is "The 4-point DFT of the given function is x(0)=2, x(1)=0, x(2)=0, and x(3)=0. The magnitude of the DFT spectrum is 2, 0, 0, 0. The graph of the magnitude of the DFT spectrum is as shown above."
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Design a three stepped distance protection for the protection of an EHV transmission line. Explain / label all the steps and constraints using circuit diagram(s) as well. Put together your proposed scheme considering the trip contacts configuration of the circuit breaker(s).
Distance protection is a type of protection scheme used in power system transmission line protection. It provides good selectivity and sensitivity in identifying the faulted section of the line.
The main concept of distance protection is to compare the voltage and current of the protected line and calculate the distance to the fault. This protection is widely used in Extra High Voltage (EHV) transmission lines. Design of three-stepped distance protection: Three-stepped distance protection for the EHV transmission line can be designed using the following steps:
Step 1: Zone 1 protection For the first step, we use the distance relay to provide Zone 1 protection. This relay is located at the beginning of the transmission line, and its reach is set to cover the full length of the line plus the length of the adjacent feeder. The relay uses the phase-to-phase voltage (Vab, Vbc, Vca) and the three-phase current (Ia, Ib, Ic) to measure the impedance of the line. If the calculated impedance falls below a set threshold, the relay trips the circuit breaker. The circuit diagram of Zone 1 protection is as follows:
Step 2: Zone 2 protection For the second step, we use the distance relay to provide Zone 2 protection. This relay is located at a distance from the substation, and its reach is set to cover the full length of the transmission line plus a margin. The relay uses the phase-to-phase voltage (Vab, Vbc, Vca) and the three-phase current (Ia, Ib, Ic) to measure the impedance of the line. If the calculated impedance falls below a set threshold, the relay trips the circuit breaker. The circuit diagram of Zone 2 protection is as follows:
Step 3: Backup protection For the third step, we use the overcurrent relay to provide backup protection. This relay is located at the substation and uses the current of the transmission line to measure the fault current. If the fault current exceeds a set threshold, the relay trips the circuit breaker. The circuit diagram of the backup protection is as follows:
Constraints: There are some constraints that we need to consider while designing three-stepped distance protection for the EHV transmission line. These are as follows:• The reach of each zone should be set appropriately to avoid false tripping and ensure proper selectivity.• The time delay of each zone should be coordinated to avoid overreach.• The CT ratio and PT ratio should be chosen such that the relay operates correctly.• The trip contact configuration of the circuit breaker should be considered while designing the protection scheme.
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Determine the design heating load for a residence, 30 by 100 by 10 ft (height), to be located in Windsor Locks, Connecticut (design indoor temperature is 72 F and 30% RH and outdoor temperature is 3 F and 100% RH), which has an uninsulated slab on grade concrete floor (F-0.84 Btu/ft). The construction consists of Walls: 4 in. face brick (R=0.17), % in plywood sheathing (R=0.93), 4 in. cellular glass insulation (R=12.12), and / in. plasterboard (R=0.45) Ceiling/roof: 3 in. lightweight concrete deck (R=0.42), built-up roofing (R=0.33), 2 in. of rigid, expanded rubber insulation (R=9.10), and a drop ceiling of 7 in, acoustical tiles (R=1.25), air gap between rubber insulation and acoustical tiles (R=1.22) Windows: 45% of each wall is double pane, nonoperable, metal-framed glass with 1/4 in, air gap (U-0.69) Doors: Two 3 ft by 7 A, 1.75 in. thick, solid wood doors are located in each wall (U-0.46) All R values are in hr ft F/Btu and U values are in Btu/hr ft F units. R=1/U.
Design Heating Load Calculation for a residence located in Windsor Locks, Connecticut with an uninsulated slab on grade concrete floor and different construction materials is given below: The heating load is calculated by using the formula:
Heating Load = U × A × ΔTWhere,U = U-value of wall, roof, windows, doors etc.A = Total area of the building, walls, windows, roof and doors, etc.ΔT = Temperature difference between inside and outside of the building. And a drop ceiling of 7 in,
acoustical tiles (R = 1.25)Air gap between rubber insulation and acoustical tiles (R = 1.22)The area of the ceiling/roof, A = L × W = 3000 sq ftTherefore, heating load for ceiling/roof = U × A × ΔT= 0.0813 × 3000 × (72 - 3)= 17973 BTU/hrWalls:4 in.
face brick (R = 0.17)0.5 in. plywood sheathing (R = 0.93)4 in. cellular glass insulation (R = 12.12)And 0.625 in. Therefore, heating load for walls = U × A × ΔT= 0.0731 × 5830 × (72 - 3)= 24315 BTU/hrWindows:
45% of each wall is double pane, nonoperable, metal-framed glass with 1/4 in. air gap (U = 0.69)Therefore, heating load for doors = U × A × ΔT= 0.46 × 196 × (72 - 3)= 4047 BTU/hrFloor:
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Considering the above scenario, the engineer should make a report/presentation explaining the process of design on different component and its manufacturing; finally, an integration as a complete system. (Process of VR design (constraints and criteria), components of manufacturing a fountain including audio system and lights display and any other auxiliary (fire-works display, multiple screen and advertising screens)
For the process of VR design, the engineer should start by considering the constraints and criteria. The engineer should first consider the specific requirements of the client in terms of the design of the fountain. The constraints may include the size of the fountain, the materials that will be used, and the budget that the client has allocated for the project.
After considering the constraints and criteria, the engineer should start designing the fountain using virtual reality technology. Virtual reality technology allows engineers to design complex systems such as fountains with great accuracy and attention to detail. The engineer should be able to create a virtual model of the fountain that incorporates all the components that will be used in its manufacture, including the audio system and the lights display.
Once the design is complete, the engineer should then proceed to manufacture the fountain. The manufacturing process will depend on the materials that have been chosen for the fountain. The engineer should ensure that all the components are of high quality and meet the specifications of the client.
Finally, the engineer should integrate all the components to create a complete system. This will involve connecting the audio system, the lights display, and any other auxiliary components such as fireworks displays and multiple screens. The engineer should also ensure that the fountain meets all safety and regulatory requirements.
In conclusion, the engineer should prepare a report or presentation that explains the process of designing and manufacturing the fountain, including all the components and the integration process. The report should also highlight any challenges that were encountered during the project and how they were overcome. The engineer should also provide recommendations for future improvements to the design and manufacturing process.
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ie lbmol of pentane gas (C₅H₁₂) reacts with the theoretical amount of air in a closed, rigid tank. Initially, the reactants are at 77°F, 1 m. After complete combustion, the temperature in the tank is 1900°R. Assume air has a molar analysis of 21% O₂ and 79% N₂. Determine the heat transfer, in Btu. Q = i Btu
The heat transfer, Q, can be calculated using the equation:
Q = ΔHc + ΔHg. To determine the heat transfer in Btu for the given scenario, we need to calculate the heat released during the combustion of pentane and the subsequent increase in temperature of the gases in the tank.
Where ΔHc is the heat released during combustion and ΔHg is the heat gained by the gases in the tank due to the increase in temperature. To calculate ΔHc, we need to determine the moles of pentane reacted and the heat of combustion per mole of pentane. Since pentane reacts with air, we also need to consider the moles of oxygen available in the air. The heat of combustion of pentane can be obtained from reference sources. To calculate ΔHg, we can use the ideal gas law and the given initial and final temperatures, along with the molar analysis of air, to determine the change in enthalpy. By summing up ΔHc and ΔHg, we can obtain the total heat transfer, Q, in Btu. It's important to note that the actual calculations involve several steps and equations, including stoichiometry, enthalpy calculations, and gas laws. The specific values and formulas needed for the calculations are not provided in the question, so an exact numerical result cannot be determined without that information.
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