The design for a new cementless hip implant is to be studied using an instrumented implant and a fixed simulated femur.
Assuming the punch applies an average force of 2 kN over a time of 2 ms to the 200-g implant, determine (a) the velocity of the implant immediately after impact, (b) the average resistance of the implant to penetration if the implant moves 1 mm before coming to rest.

Answer:

The answer to this question is attached fully with the explanation.

Answer:

2.46 * 10⁵ W/m³

Explanation:

See attached pictures for detailed explanation.

Answer:

[tex]q^.=2.46*10^5W/m^3[/tex]

Explanation:

[tex]Given\\k=2.5W/m\\h_{1} =75(left)\\h_{2} =50(right)\\T_{1} =50^oC\\T_{2} =30^oC[/tex]

so

[tex]T=-\frac{q^.x^2}{2k} +c_{1}x+ c_{2} \\T=T_{1} \\at \\x=-0.04\\T=T_{2} \\at\\x=+0.04[/tex]

[tex]dT/dx=-q^.x/k+c_{1} \\T=T_{max} =300\\at\\x=c_{1} \frac{k}{q^.} (1)[/tex]

[tex]h_{1}(T_{1infinity} -T_{1} )=-k\frac{dT}{dx} |_{x=0.04} (2)\\-k\frac{dT}{dx} |_{x=0.04} =h_{2} (T_{2}-T_{2infinity} (3)[/tex]

[tex]300=-\frac{q^.}{2k} [c_{1} \frac{k}{q} ]^2+c_{1} [c_{1} \frac{k}{q} ]+c_{2} (1)[/tex]

[tex]75[50+\frac{q^2}{2k} (0.04)^2+c_{1} (0.04)-c_{2} ]=-k[\frac{+q^2(0.04)}{2k} ](2)[/tex]

[tex]-k[\frac{-q^.(0.04)}{2k} ]=50[\frac{-q^.(0.04)}{2k} +c_{1} (0.04)+c_{2} -30](3)[/tex]

solving above 3 equations for 3 unknowns c1,c2,q

we get [tex]q^.=2.46*10^5W/m^3[/tex]

Answer:

Radius = 1565ft  ;  PC = 245 + 11.13  ; PT = 255 + 48.88

Explanation:

1. Accordingly to the law of mechanics;

Centrifugal factor =S+F = V²/15R

Where; S = Super-elevation slope = 0.07ft/ft

F= Slide friction factor

V= Design speed=65mi/h

R= Radius

From the graph (see attached), at design speed of 65mi/h, coefficient of slide friction factor, F =0.11

Applying the figures in the equation above;

0.07+0.11 = 65²/15R

R=281.67/0.18

R=1564.8

Approximately Radius = 1565ft

2. Stationing PC = Stationing PI - T

where T = Tangent distance

T= Rtan(Δ/2) where Δ = central angle = 38° & Stationing PI = 250 + 50

T=1565tan19°

T=538.87ft

Stationing PC = 250 + 50 - (5 + 38.87)

PC = 245 + 11.13

3. Stationing PT = Stationing PC + L

Where L = Length of the circular curve

L = π/180*(RΔ)

L=0.01745*1565*38

L=1037.75

Therefore;

Stationing PT= 245 + 11.13 + (10 +37.75)

PT = 255 + 48.88

Answer:

The purpose of the algorithm is to print the least digit among a total of 15 digita

Explanation:

input somenum

Repeat the following steps for 14 times

input variable1

if variable1 < somenum then

somenum = variable1

print somenum

On line 1, the algorithm takes an input through variable1

An iteration is started on line 2 and ends on line 6

Line 3,4,5 re performed repeatedly;

On line 3, the algorithm accepts another input through somenum and it keep accepting it till the end of the iteration.

On line 4, the algorithm tests if variable1 is lesser than somenum.

If yes, line 5 is executed and the value of variable1 is assigned to somenum

Else, line 5 is skipped; the iteration moves to line 3 as long as the condition is still valid.

At the end of the iteration, the least value stored in somenum is printed through

Answer:

a) 44.4%

b) 72 mm

Explanation:

See attached pictures.

a. The field relative density is 44.44%.

b. A 3 m thick stratum of this sand will settle by 0.111 m when densified to a relative density of 65%.

Let's solve the problem step-by-step.

Given Data

- Wet density of sand [tex](\( \rho_{wet} \)) = 1.9 Mg/m\(^3\)[/tex]

- Field water content ( w ) = 10% = 0.10

- Density of solids [tex](\( \rho_s \))[/tex] = 2.66 [tex]Mg/m\(^3\)[/tex]

- Maximum void ratio [tex](\( e_{max} \))[/tex] = 0.62

- Minimum void ratio [tex](\( e_{min} \))[/tex] = 0.44

a. Calculation of Field Relative Density

First, we need to calculate the dry density of the sand:

[tex]\[ \rho_{dry} = \frac{\rho_{wet}}{1 + w} = \frac{1.9}{1 + 0.10} = \frac{1.9}{1.10} = 1.727 \text{ Mg/m}^3 \][/tex]

Now, we use the dry density to find the void ratio  e :

[tex]\[ e = \frac{\rho_s}{\rho_{dry}} - 1 = \frac{2.66}{1.727} - 1 = 1.54 - 1 = 0.54 \][/tex]

Relative density [tex](\( D_r \))[/tex] is given by the formula:

[tex]\[ D_r = \frac{e_{max} - e}{e_{max} - e_{min}} \times 100\% \][/tex]

Substituting the values:

[tex]\[ D_r = \frac{0.62 - 0.54}{0.62 - 0.44} \times 100\% = \frac{0.08}{0.18} \times 100\% = 44.44\% \][/tex]

b. Settlement Calculation

To find the settlement of a 3 m thick stratum of sand when densified to a relative density of 65%, we need to determine the void ratio corresponding to 65% relative density.

[tex]\[ D_r = 65\% = 0.65 \][/tex]

Using the relative density formula again, solve for  e :

[tex]\[ 0.65 = \frac{e_{max} - e_{new}}{e_{max} - e_{min}} \][/tex]

[tex]\[ 0.65 = \frac{0.62 - e_{new}}{0.62 - 0.44} \][/tex]

[tex]\[ 0.65 \times (0.62 - 0.44) = 0.62 - e_{new} \][/tex]

[tex]\[ 0.65 \times 0.18 = 0.62 - e_{new} \][/tex]

[tex]\[ 0.117 = 0.62 - e_{new} \][/tex]

[tex]\[ e_{new} = 0.62 - 0.117 = 0.503 \][/tex]

Now calculate the initial and final volumes of voids:

Initial void ratio [tex]\( e_{initial} = 0.54 \)[/tex]

Final void ratio [tex]\( e_{new} = 0.503 \)[/tex]

Initial volume of voids [tex]\( V_{v_initial} \):[/tex]

[tex]\[ V_{v_initial} = e_{initial} \times V_s \][/tex]

Final volume of voids [tex]\( V_{v_final} \):[/tex]

[tex]\[ V_{v_final} = e_{new} \times V_s \][/tex]

The change in void volume:

[tex]\[ \Delta V_v = V_{v_initial} - V_{v_final} = (e_{initial} - e_{new}) \times V_s \][/tex]

For the 3 m thick stratum:

[tex]\[ \Delta H = \Delta V_v \][/tex]

[tex]\[ \Delta H = (e_{initial} - e_{new}) \times H \][/tex]

[tex]\[ \Delta H = (0.54 - 0.503) \times 3 \text{ m} \][/tex]

[tex]\[ \Delta H = 0.037 \times 3 \text{ m} \][/tex]

[tex]\[ \Delta H = 0.111 \text{ m} \][/tex]

So, the sand stratum will settle by 0.111 m when densified to a relative density of 65%.

Answer:

Please find attached file for complete answer.

Explanation:

Answer: Let us use the pickled file - DeckOfCardsList.dat.

Explanation: So that our possible outcome becomes

7♥, A♦, Q♠, 4♣, 8♠, 8♥, K♠, 2♦, 10♦, 9♦, K♥, Q♦, Q♣

HPC (High Point Count) = 16  

The length of Bridge B is expressed as m - 5555 feet, where m represents the length of Bridge A. For example, if Bridge A is 10,000 feet long, then Bridge B would be 4445 feet long.

Bridge B is 5555 feet shorter than Bridge A, so we can represent the length of Bridge B as m - 5555 feet. This expression represents the length of Bridge B in terms of m, where m represents the length of Bridge A. For example, if Bridge A is 10,000 feet long, then Bridge B would be 10,000 - 5555 = 4445 feet long.

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Answer:

1.757 kg/s

Explanation:

According to the First Law of Thermodynamics, the physical model for a turbine working at steady state is:

[tex]-\dot Q_{out} - \dot W_{out} + \dot m \cdot (h_{in}-h_{out})=0[/tex]

The flow rate of steam is:

[tex]\dot m = \frac{\dot Q_{out}+\dot W_{out}}{h_{in}-h_{out}}[/tex]

Water enters and exits as superheated steam. After looking for useful data in a property table for superheated steam, specific enthalpies at inlet and outlet are presented below:

[tex]h_{in} = 3451.7 \frac{kJ}{kg} \\h_{out} = 2967.9 \frac{kJ}{kg} \\[/tex]

Finally, the flow rate is calculated:

[tex]\dot m = \frac{100 kW + 750 kW}{3451.7 \frac{kJ}{kg} - 2967.9 \frac{kJ}{kg}}\\\dot m =1.757 \frac{kg}{s}[/tex]

Answer:

Part (a)

K = 0.00406 m / s

T = 0.14 m2 / s

Part (b)

R = Radius of influence of Pumping well = 237.94 m

Part (c)

S = Drawdown at well = 3.68 m

Explanation:

General formula for wells at confined aquifer is

Where ,

    Q = Discharge

    K = Hydraulic conductivity

    B = Thickness of aquifer

    S1 = Draw-down at point 1

    S2 = Draw-down at point 2

    R = Radius of influence of well

    r =  Radius of well

Part (a)

We will use

Where,

    r 1 = Distance of first observation well from main well

    r2 = Distance of 2nd observation well from main well

Given data:  Q = 0.5 m3/s       B = 34 m            r 1 = 50 m  

                     r2 = 100 m          S1 = 0.9 m          S2 = 0.4 m

Put all these values in equation 1

  0.5 = 2*3.1416*K*34*(0.9 - 0.5) / {2.303 log(100 / 50)}

Write Equation in terms of K = hydraulic conductivity

 K = {0.5*2.303 log (100 / 50)} / {2*3.1416*34*(0.9 - 0.5)}

 K = 0.00406 m / s

Now Transmissivity

  T = K*B

  T = 0.14 m2 / s

Part (b)

To calculate radius of influence, use equation (A)  

  Q = [tex]{2*3.1416*K*B*(S1-S2)} / {2.303 log (R/r)}[/tex]

  At distance R from main well drawdown (S2) = 0

  use r = r1 = 50 m and S1 = 0.9

  use ln ( R / r) = 2.303 log (R / r)

  0.5 = 2* 3.1416 * 0.00406*34* (0.9 - 0) / ln(R / 50)

  Write equation in terms of R

  ln( R / 50) =  2* 3.1416 * 0.00406*34* (0.9 - 0) / 0.5

  ln( R / 50) = 1.56

  Take anti log (e) of above equation

  R / 50 = 4.76

  R = Radius of influence of Pumping well = 237.94 m

Part (c)

 Use equation A

 Q = [tex]{2*3.1416*K*B*(S1-S2)} / {2.303 log (R/r)}[/tex]

 S1 = ?            

Put S2 = 0         R = 237.94           r = 0.4

0.5 = 2* 3.1416* 0.00406*34*(S1 - 0) / 2.303 log(237.94 / 0.4)

Write equation in terms of S1

S1 = 0.5* 2.303 log(237.94 / 0.4) / 2*3.1416*0.00406*34

S1 = Drawdown at well = 3.68 m

The hydraulic conductivity and transmissivity of the aquifer are respectively; 0.0032 m/s and 0.11 m³/s

A) We are given;

Pump rate; Q = 0.5 m³/s

thickness of quifer; b = 34 m

depth 1; r₁ = 50 m

depth 2; r₂ = 100 m

distance 1; S₁ = 0.9 m

distance 2; S₂ = 0.4 m

Formula for the pump rate is;

Q = 2π × b × k × (S₁ - S₂)/(In r₂/r₁)

making k the subject gives;

k = Q(In r₂/r₁)/(2π × b × (S₁ - S₂))

k = 0.5(In 100/50)/(2π × 34 × (0.9 - 0.4))

Solving for K gives;

Hydraulic conductivity is; k = 0.0032 m/s

Transmissivity is;

T = K * b

T = 0.0032 * 34

T = 0.11 m³/s

B) Formula for radius of incfluence is;

S_w = S₁ - [(Q/2π × b × k) In (r_w/r₁)]

Plugging in the relevant values gives;

S_w = 4.338 m

C) Formula for expected drawdown is;

R = r₁ e^(2πbk(S_w - S₁)/Q)

R = 100 * e^(2π*34*0.0032(-78.9)/0.5)

R = 147.7 m

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Answer:

B

Explanation:

Torsion is application of torque to a shaft to turn it about its longitudinal axis. When torque is applied to a shaft the circle remains unchanged in a circular state, its cross section does not warp but remains flat with a straight radial lines but its longitudinal lines changes into an helix intersecting the circular shaft

Answer:

[tex]q_{out} = 9.25\,\frac{kJ}{kg}[/tex]

Explanation:

First, it is required to find the absolute humidity of air at initial state:

[tex]\omega = \frac{0.622\cdot \phi \cdot P_{g}}{P-\phi \cdot P_{g}}[/tex]

The saturation pressure at [tex]T = 27^{\textdegree}C[/tex] is:

[tex]P_{g} = 3.601\,kPa[/tex]

Then,

[tex]\omega = \frac{0.622\cdot (0.5)\cdot (3.601\,kPa)}{101.325\,kPa-(0.5)\cdot (3.601\,kPa)}[/tex]

[tex]\omega = 0.0113\,\frac{kg\,H_{2}O}{kg\,air}[/tex]

A simple cooling process implies a cooling process with constant absolute humidity. The specific entalphies for humid air are:

Initial state:

[tex]h_{1} = (1.005\,\frac{kJ}{kg\cdot ^{\textdegree}C})\cdot (27^{\textdegree}C)+(0.0113)\cdot (2551.96\,\frac{kJ}{kg} )[/tex]

[tex]h_{1} = 55.972\,\frac{kJ}{kg}[/tex]

Final state:

[tex]h_{2} = (1.005\,\frac{kJ}{kg\cdot ^{\textdegree}C})\cdot (18^{\textdegree}C)+(0.0113)\cdot (2533.76\,\frac{kJ}{kg} )[/tex]

[tex]h_{2} = 46.722\,\frac{kJ}{kg}[/tex]

The specific energy that is removed is:

[tex]q_{out}= h_{1} - h_{2}[/tex]

[tex]q_{out} = 9.25\,\frac{kJ}{kg}[/tex]

Answer:

it will take for the casting to solidify 2.55 min

Explanation:

given data

mold constant = 4 min/cm²

length = 35 cm

width = 10 cm

thickness = 15 mm

solution

we use here Chvorinov's Rule that is

Chvorinov's Rule = mold constant × [tex](\frac{V}{A})^{1.9}[/tex]   ..............1

put here value

Chvorinov's Rule = 4 × [tex](\frac{600}{760})^{1.9}[/tex]  

Chvorinov's Rule = 2.55 min/in

so heer unit flow become [tex]min/in^{1.9}[/tex]  

Answer:

A. 0.020

B. 0.018

Explanation: check the attached file

Answer:

a. n=0.020  b. n=0.018

Explanation:

a.

Case 1: To line the sides only

n=(Σn₁¹°⁵P₁)^2/3/P^2/3

n = equivalent roughness

n₁=corresponding roughness coefficients

P=length

At the bed: n₁=0.025 and P₁=5m

At the sides: n₂=0.012 and P₂= 2*1.1*√1+1.5²=2.2*1.8=3.96m

P = P₁+P₂=8.96m

Equivalent roughness, n = [5*(0.025)^1.5+3.96*(0.012)^1.5]^2/3/(8.96)^2/3

n= [(5*0.00395)+(3.96*0.0013)]^2/3/4.317

n=0.0249^2/3/4.317

n=0.0842/4.317

n=0.0195

n=0.020

b.

Case 2: To line the bed only

P₁=5m   n₁=0.012

P₂=3.96 n₂=0.025

P=8.96

Equivalent roughness n= [5*(0.012)^1.5+3.96*(0.025)^1.5]^2/3/(8.96)^2/3

n=[(5*0.0013)+(3.96*0.00395)]^2/3/4.317

n=0.0221^2/3/4.317

n=0.078/4.317

n=0.018

Based on the available information, the the estimated towing power required is:

(a) For the parallel orientation: 655 kW

(b) For the normal orientation: 4,116.75 kW

Given:

- Diameter of the cylinder: 1.5 m

- Length of the cylinder: 22 m

- Towing speed (U): 5 m/s

- Water temperature: 20°C

(a) Cylinder parallel to the tow direction:

Step 1: Calculate the drag force for the parallel orientation.

The drag force for a submerged cylinder in parallel orientation is given by the formula:

F_D = 0.5 × ρ × C_D × A × U^2

Where:

- ρ is the density of fresh water at 20°C, which is approximately 998 kg/m³.

- C_D is the drag coefficient for a cylinder in parallel orientation, which is approximately 0.82.

- A is the cross-sectional area of the cylinder, which is π × D × L = π × 1.5 m × 22 m = 103.87 m².

Calculating the drag force:

F_D = 0.5 × 998 kg/m³ × 0.82 × 103.87 m² × (5 m/s)² = 131,000 N

Step 2: Calculate the towing power for the parallel orientation.

Towing power = Drag force × Towing speed

Towing power = 131,000 N × 5 m/s = 655,000 W = 655 kW

(b) Cylinder normal to the tow direction:

Step 3: Calculate the drag force for the normal orientation.

The drag force for a submerged cylinder in normal orientation is given by the formula:

F_D = 0.5 × ρ × C_D × A × U^2

Where:

- C_D is the drag coefficient for a cylinder in normal orientation, which is approximately 1.2.

- A is the cross-sectional area of the cylinder, which is π × D × D/4 = π × 1.5 m × 1.5 m/4 = 1.77 m².

Calculating the drag force:

F_D = 0.5 × 998 kg/m³ × 1.2 × 1.77 m² × (5 m/s)² = 823,350 N

Step 4: Calculate the towing power for the normal orientation.

Towing power = Drag force × Towing speed

Towing power = 823,350 N × 5 m/s = 4,116,750 W = 4,116.75 kW

Therefore, the estimated towing power required is:

(a) For the parallel orientation: 655 kW

(b) For the normal orientation: 4,116.75 kW

Answer:

[tex]W= 3.22 \mu m[/tex]

Explanation:

the transistor In saturation drain current region is given by:

[tex]i_D}=K_a(V_{GS}-V_{IN})^2[/tex]

Making [tex]K_a[/tex] the subject of the formula; we have:

[tex]K_a=\frac {i_D} {(V_{GS} - V_{IN})^2}[/tex]

where;

[tex]i_D = 1.2m[/tex]

[tex]V_{GS}= 3.0V[/tex]

[tex]V_{TN} = 0.6 V[/tex]

[tex]K_a=\frac {1.2m} {(3.0 - 0.6)^2}[/tex]

[tex]K_a = 208.3 \mu A/V^2[/tex]

Also;

[tex]k'_n}=\frac{\mu n (\frac{cm^2}{V-s} ) \epsilon _{ox}(\frac{F}{cm} ) }{t_{ox}(cm)}[/tex]

where:

[tex]\mu n (\frac{cm^2}{V-s} ) = 600[/tex]

[tex]\epsilon _{ox}=3.9*8.85*10^{-14}[/tex]

[tex]{t_{ox}(cm)=200*10^{-8}[/tex]

substituting our values; we have:

[tex]k'_n}=\frac{(600)(3.988.85*10^{-14})}{(200*10^{-8})}[/tex]

[tex]k'_n}=103.545 \mu A/V^2[/tex]

Finally, the width can be calculated by using the formula:

[tex]W= \frac{2LK_n}{k'n}[/tex]

where;

L = [tex]0.8 \mu m[/tex]

[tex]W= \frac{2*0.8 \mu m *208.3 \mu}{103.545 \mu}[/tex]

[tex]W= 3.22 \mu m[/tex]

Answer:

note:

solution is attached in word form due to error in mathematical equation. furthermore i also attach Screenshot of solution in word due to different version of MS Office please find the attachment

The voltage of the source can be determined by dividing the total energy transferred (sum of the paddle-wheel work and heat required to evaporate water) by the product of current and time. The process will be seen as a horizontal line on a piston-cylinder diagram

The heat transferred to the water can be calculated from the energy supplied by the electrical source and the work done by the paddle wheel. Since power is the energy transferred per unit time, we can use the equation Power = Voltage x Current. We know that the current is 8 A and the energy transferred is the sum of the work done by the paddle wheel and the heat required to evaporate half of the water, which is 45 minutes (converted to seconds) times the power. Solving for voltage we get:

Voltage = (Energy transferred) / (Current x Time)

In terms of a piston-cylinder diagram, the process will appear as a horizontal line since the pressure is constant. The line will move upwards as heat is added and some of the water is turned into steam.

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Answer:

Explanation:

The method or principle applied is the Routh- hurtwitz criterion for solving characteristics equation.

The steps by step analysis and appropriate substitution is carefully shown in the attached file.

Answer:

The solution to the given problem is provided below.

Explanation:

a.) myBike.height = 26;                                                 Not Legal statement

b.) myBike.model = “Cyclone”:                                    Legal statement

c.) myBike.wheels = 3;                                                  Legal statement

d.) myBike.model = 108;                                               Not legal statement

e.) Bicycle.height = 24;                                                  Not Legal statement

f.) Bicycle.model = “Hurricane”;                                 Not legal statement

g.) Bicycle.int = 3;                                                           Not Legal statement

h.) Bicycle.model = 108;                                                Not Legal Statement

i.) Bicycle.wheels = 2;                                                    Legal Statement

j.) Bicycle yourBike = myBike;                                      Legal Statement

The output voltage from a Wheatstone bridge with a change in temperature of 20℃ in one of its platinum resistance temperature sensor arms is calculated to be approximately 0.233 V, taking into account the specific temperature coefficient of resistance for platinum.

The student's question involves calculating the output voltage from a Wheatstone bridge when a platinum resistance temperature sensor, which forms one arm of the bridge, changes its resistance due to a temperature change. With a temperature coefficient of resistance for platinum of 0.0039/K and an initial balance condition at 0℃ with each arm having a resistance of 120 Ω, the temperature change of 20℃ will lead to a change in resistance in the platinum arm, affecting the bridge's balance and generating an output voltage.

To calculate the change in resistance (ΔR) for the platinum sensor due to the temperature change: ΔR = Ro·α·ΔT, where Ro is the initial resistance (120 Ω), α is the temperature coefficient of resistance (0.0039/K), and ΔT is the temperature change (20℃). Therefore, ΔR = 120·0.0039·20 = 9.36 Ω. The new resistance of the platinum sensor at 20℃ is 120 Ω + 9.36 Ω = 129.36 Ω.

Given the supply voltage (Vs) is 6.0 V, and considering the bridge was initially balanced, the output voltage (Vo) from the bridge can be calculated using the formula derived from the Wheatstone bridge principles: Vo = Vs · (ΔR / (2Ro + ΔR)). Substituting the values gives Vo = 6.0 · (9.36 / (240 + 9.36)) = 0.233 V. Thus, the output voltage from the bridge for a change in temperature of 20℃ is approximately 0.233 V.

Answer:

Please find attached file for complete answer solution and explanation of same question.

Explanation:

Answer:

59.78 m

Explanation:

Data:

PI station = 250 will allow a speed of 65 mph

The maximum superelevation will be  = 0.08 ft/ft

Central angle of the curve                    =  35 degrees

A figure will be used to present the information. This gives the height of 59.78 m as the maximum elevation for the safe speed of the vehicle.

Answer:

a) The forward voltage is 0.23 V

b) The current that flows  [tex]I_{d} = (1.45*10^{12}I_{s})A[/tex]

Explanation:

The forward voltage is the minimum voltage that must be applied to a diode before it starts to conduct. The equation is given by:

a) At what forward voltage does a diode conduct a current equal to 10,000 Is ? In terms of Is

[tex]I_{d} = I_{s}(e^{\frac{v_{f} }{0.025} }-1)[/tex]

Where:

Id is the diode current = 10000Is,

Vd is the forward voltage at which the diode begins to conduct,

Is is the saturation current.

[tex]I_{d} = I_{s}(e^{\frac{v_{f} }{0.025} }-1)[/tex]

[tex]10000I_{s} = I_{s}(e^{\frac{v_{f} }{0.025} }-1)[/tex]

Dividing through by Is,

[tex]10000 = (e^{\frac{v_{f} }{0.025} }-1)[/tex]

[tex]10000 +1= e^{\frac{v_{f} }{0.025} }[/tex]

[tex]10001= e^{\frac{v_{f} }{0.025} }[/tex]

Taking the natural logarithm of both sides,

[tex]ln(10001)= {\frac{v_{f} }{0.025} }[/tex]

[tex]9.21= {\frac{v_{f} }{0.025} }[/tex]

multiplying through by 0.025

[tex]{v_{f} }= 0.23[/tex] = 0.23 V

The forward voltage does a diode conduct a current equal to 10,000 Is is 0.23 V

b) what current flows in the same diode when its forward voltage is 0.7 V?

[tex]I_{d} = I_{s}(e^{\frac{v_{f} }{0.025} }-1)[/tex]

[tex]I_{d} = I_{s}(e^{\frac{0.7}{0.025} }-1)[/tex]

[tex]I_{d} = I_{s}(1.45*10^{12} -1)[/tex]

[tex]I_{d} = (1.45*10^{12}I_{s})A[/tex]

Answer:

The most common approach to accessing an array is to use a for loop:

var mammals = new Array("cat","dog","human","whale","seal");

var animalString = "";

for (var i = 0; i < mammals. length; i++) {

animalString += mammals[i] + " ";

}

alert(animalString);

Discussion

A for loop can be used to access every element of an array. The array begins at zero, and the array property length is used to set the loop end.

Though support for both indexOf and lastIndexOf has existed in browsers for some time, it’s only been formalized with the release of ECMAScript 5. Both methods take a search value, which is then compared to every element in the array. If the value is found, both return an index representing the array element. If the value is not found, –1 is returned. The indexOf method returns the first one found, the lastIndexOf returns the last one found:

var animals = new Array("dog","cat","seal","walrus","lion", "cat");

alert(animals.indexOf("cat")); // prints 1

alert(animals.lastIndexOf("cat")); // prints 5

Both methods can take a starting index, setting where the search is going to start:

var animals = new Array("dog","cat","seal","walrus","lion", "cat");

alert(animals.indexOf("cat",2)); // prints 5

alert(animals.lastIndexOf("cat",4)); /

Answer:

animals = ["Dog", "Lion", "Goat", "Zebra", "Cat"]

           for animal in animals:

                       print(animal)

x = animals.insert(5, "Lizard")

y = animals.insert(6, "Bat")

z = sorted(animals)

print(z)

Explanation:

The question can be solved using various back-end coding language like python, java, JavaScript etc. But I will be writing the code with python.

The first question said we should create an array or list of five animals.

animals = ["Dog", "Lion", "Goat", "Zebra", "Cat"]  → I created the five animals in a list and stored them in the variable animals.

for animal in animals:  I used a for loop to iterate through the list print(animal)  I used print statement to display the values stored in the array or list.

x = animals.insert(5, "Lizard")  I added an animal, lizard to the end of the array

y = animals.insert(6, "Bat")  I added another animal , Bat to the end of the array.

z = sorted(animals)  I sorted the array according to alphabetical number.

print(z) I displayed the sorted array .

Answer:

See step to step explanations for answer.

Explanation:

This is the expression to check if credits is less than 0 assuming variable name is credits:

if(credits<0)

{

credits = 0;

}

Q 4.69:

this is the expression checking the name is Swordfish or not

if(name=="Swordfish")

{

cout<<"We have a match";

}

Q 4.67

This is the expression to check the character assuming that character is ch

if(ch>='1' && ch<='9')

{

cout<<"Digit detected";

}

Q 4.59:

This is the statement to check if the number is between 0 and 500 inclusive . Assuming the variable is n

if(n>=0 && n<=500)

{

cout<<"The number is valid";

}

To address the programming question about conditional expressions, a ternary operator can be used to set the variable 'credits' to 0 if its value is less than 0, and otherwise keep the current value.

The student's question pertains to the use of a conditional expression in a programming context. A conditional expression evaluates a condition and based on its truth value, executes one of two expressions. The statement required should check if the credits variable is less than 0 and if so, assign the value 0 to credits; otherwise, it should leave the value of credits as is.

An example in a generic programming language would be:

This line of code is known as a ternary operator or conditional assignment. It reads as 'Set credits to 0 if credits is less than 0; otherwise, keep the value of credits.'

Answer:

d = 0.868 in

Explanation:

note:

solution is attached due to error in mathematical equation. please find the attachment

This question involves solving for the diameter d at the portion BC of a steel rod under axial load. It involves utilizing Hooke's Law and expressing cross-sectional area in terms of diameter. The final calculation will depend on the length of the portion BC.

The question appears to involve the concept of stress and strain in the area of mechanical engineering. In this problem, we have a steel rod ABC, where end C, experiencing a single axial load P = 15 kips, deflections to 0.05 inches. We are tasked to find the diameter, denoted as d, of portion BC.

To solve this, we could utilize Hooke's Law of elasticity that connects stress, strain, and the Young's modulus (E). The formula is represented as δ = PL/AE. In the equation, P is the load, L is the length, A is the cross-sectional area and E is Young's modulus. We are given P, E, and δ (deflection), leaving the cross-sectional area and length as variables to be found. Since we are looking for the diameter (d), we need to express the area (A) in terms of the diameter using the formula A = πd²/4.

The length L is dependent on the specific conditions of the problem and are not given directly. Depending on the conditions, L might need to be solved differently. First, solve the equation for diameter, afterwards, plug the known values in and evaluate, giving the diameter in inches of the steel rod at portion BC.

https://brainly.com/question/36010339

#SPJ2

Answer:

11.65 minutes.

Explanation:

See the attached picture for detailed explanation.

Answer:

11.65 min

Explanation:

Hydrogen sulfide is very poisonous and as a result, it is essential to reduce the concentration of the gas to the lowest possible value to minimize its effects. The time taken to reduce the amount of hydrogen sulfide in the system to the allowable limit can be estimated as shown below:

t = (V/Q)*ln(Ci/Co) = (160/10)*ln(14/29) = 16*0.728 = 11.65  min

To calculate the required cross-sectional area of copper wires needed to connect the DC supply source to the mine lights with less than 5% power loss, calculate the permissible power loss, and then use the relationship between power loss, current, and wire resistance. Considering the resistivity of copper and the round trip length of the wire, the formula A = ρL/(δP/I²) determines the necessary wire thickness.

To determine the required cross-sectional area of copper wires for the lighting equipment, we need to ensure the power loss (δP) is no more than 5% of the lights' power usage (P), which is 5 kW (5000 W). As the power loss in wires is given by δP = I²R, where I is the current and R is the resistance of the wire, we must first calculate the current using P = IV, giving I = P/V = 5000W/120V = 41.67 A. The power loss allowed is thus 5% of 5000 W, equating to 250 W. Given δP, we can find R using δP = I²R, which gives R = δP/I².

The resistance of a copper wire is also given by R = ρL/A, where ρ is the resistivity of copper (1.68 x 10^-8 Ωm), L is the length of the wire (200 meters round trip), and A is the cross-sectional area we need to find. Equating the two expressions for R and solving for A gives A = ρL/(δP/I²). Substituting the given and calculated values yields the required cross-sectional area. Finally, as resistance depends on the entire length of the circuit, remember to double the distance to account for both the outgoing and return paths.

Answer:

m' = 4948.38 kg/s

Explanation:

For a case of 100% efficiency, the power produced must be equal to the rate of potential energy conversion

GIVEN THAT

Power = 100 MW

rate of Potential energy = (m')*g*h

100*10^6 = (m')*9.81*206

m' = 4948.38 kg/s

Answer:

49.484 m³ / s

Explanation:

Volume flow rate = Power in W / (efficiency × density × height × acceleration due to gravity)

Volume flow rate = 100 × 10⁶ / ( 1 × 1000 kg/m³ × 206 m × 9.81 m/s²)

V = 49.484 m³ / s

Vector addition is used to calculate the speeds of the swimmer and the water in the river, understanding relative velocity is key in solving the problem.

To determine the speed of the water in the river, we first calculate the resultant velocity of the swimmer using vector addition. The swimmer's speed with respect to a friend at rest on the ground is found by considering the swimmer's velocity and the water current's velocity. By understanding the concepts of relative velocity and vector addition, we can accurately calculate the required speeds.