A multilane highway (two lanes in each direction) is on level terrain. The free-flow speed has been measured at 45 mi/h. The peak-hour directional traffic flow is 1300 vehicles with 6% large trucks and buses and 2% recreational vehicles (f_p = 0.95).If the peak-hour factor is 0.85, determine the highway's level of service.

a. It's not entirely reasonable to generalize the conclusion to all 18-year-olds with publicly accessible MySpace profiles due to the study's limited sample size and potential biases.

b. b. No, it's not reasonable to generalize the conclusion to all 18-year-old MySpace users because not all users have publicly accessible profiles.

c. While somewhat reasonable, generalizing to MySpace users with publicly accessible profiles requires caution, considering potential individual differences within this subgroup.

The study only looked at a random sample of 500 profiles, which might not be fully representative of all 18-year-olds on MySpace. Generalizing to all 18-year-old MySpace users is not reasonable as not all users have publicly accessible profiles, which could skew the findings.  

Additionally, factors such as cultural differences, regional variations, and individual preferences could influence whether adolescents choose to display sport or hobby involvement on their profiles.

See text

The article "Display of Health Risk Behaviors on MySpace by Adolescents" (Archives of Pediatrics and Adolescent Medicine [2009]:

) described a study in which researchers looked at a random sample of 500 publicly accessible MySpace web profiles posted by 18-year-olds. The content of each profile was analyzed. One of the conclusions reported was that displaying sport or hobby involvement was associated with decreased references to risky behavior (sexual references or references to substance abuse or violence).

a. Is it reasonable to generalize the stated conclusion to all 18-year-olds with a publicly accessible MySpace web profile? What aspect of the study supports your answer?

b. Not all MySpace users have a publicly accessible profile. Is it reasonable to generalize the stated conclusion to all 18-year-old MySpace users? Explain.

c. Is it reasonable to generalize the stated conclusion to all MySpace users with a publicly accessible profile? Explain.

Answer:

(a) The charges of 75 C must flow through battery.

(b) The electrons must flow from a to b.

Explanation:

(a)

The relationship between the energy and voltage is as follows:

Energy = (Voltage)(Current)(Time)

but, (current)(time) = charge

therefore,

Energy = (Voltage)(Charge)

Charge = (Energy)/(Voltage)

Charge = (900 J)/(12 V)

Charge = 75 C

(b)

Since, Vab = Va - Vb = 12 V

Hence, the equation suggest that Va is at higher potential then Vb.

As, the current flows from higher to lower potential.

Thus, electrons must flow from a to b

Answer:

(userVal < 0) ? "negative" : "non-negative" ;

Explanation:

The above code has been written using Java's ternary operator (? : ).

Java uses this operator to write conditional expressions that are similar to the regular if ... else statements.

This expression has three parts,

i. the conditional statement: this is the expression before the ? mark. In this case, (userVal < 0). This expression contains the condition to be tested for and it returns true or false.

ii. the second part is the statement after the ? mark. In this case, "negative". This expression will be executed if the conditional statement returns true.

iii. the third part is the statement after the : mark. In this case, "non-negative". This expression will be executed if the conditional statement returns false.

So in this case, if userVal < 0, the string "negative" will be evaluated. Otherwise, "non-negative".

Answer:

Time taken = 5.41mins

Explanation:

A step by step calculations with detailed explanation has been attached below.

Answer:

a) Rankine

Net work output = 719.1 KJ/kg

Thermal Eff = 0.294

a) Carnot

Net work output = 563.2 KJ/kg

Thermal Eff = 0.294

For T-s diagrams see attachments

Explanation:

Part a    Rankine Cycle

The obtained data from water property tables:

[tex]P_{L,sat liquid} = 50 KPa \\v_{1} = 0.00103m^3/kg\\\\ h_{1} = 340.54KJ/kg\\\\P_{H} = 5000KPa\\h_{2} = h_{1} + v_{1} *(P_{H} - P_{L} )\\h_{2} =350.54 + (0.00103)*(5000 - 50)\\\\h_{2} = 345.64KJ/kg\\\\P_{H,satsteam} = 5000KPa\\s_{3} = 5.9737KJ/kgK\\\\h_{3} = 2794.2KJ/kg\\\\s_{3} = s_{4} = 5.9739KJ/kgK\\P_{L}= 50KPa\\\\h_{4}= 2070KJ/kg\\\\[/tex]

Heat transferred from boiler

[tex]q_{b} = h_{3}-h_{2}\\q_{b}=2794.2-345.64\\\\q_{b} =2448.56KJ/kg\\\\[/tex]

Heat transferred from condenser

[tex]q_{c} = h_{4}-h_{1}\\q_{b}=2070-340.54\\\\q_{b} =1729.46KJ/kg\\\\[/tex]

Thermal Efficiency

[tex]u_{R} = 1- \frac{q_{c}}{q_{b}}\\\\u_{R} = 1 - \frac{1729.46}{2448.56}\\\\u_{R} =0.294[/tex]

Net work output

[tex]w_{R} = q_{b}-q_{c}\\w_{R} = 2448.56-1729.46\\\\w_{R}=719.1KJ/kg[/tex]

Part b    Carnot Cycle

The obtained data from water property tables:

[tex]P_{H,sat-steam} = 5000KPa\\T_{3} = 263.94 C\\s_{3} = 5.9737KJ/kgK\\\\h_{3} = 2794.2KJ/kg\\\\T_{2,sat-liquid} = T_{3} = 263.94C\\s_{2} = 2.920KJ/kgK\\\\h_{2} = 1150KJ/kg\\\\P_{L} = 50KPa\\s_{1}=s_{2} = 2.920KJ/kgK\\\\h_{1} = 989KJ/kg\\\\s_{3} = s_{4} = 5.9737KJ/kgK\\P_{L} = 50KPa\\\\h_{4} = 2070KJ/kg[/tex]

Heat transferred from boiler

[tex]q_{b} = h_{3}-h_{2}\\q_{b}=2794.2-1150\\\\q_{b} =1644.2KJ/kg\\\\[/tex]

Heat transferred from condenser

[tex]q_{c} = h_{4}-h_{1}\\q_{b}=2070-989\\\\q_{b} =1081KJ/kg\\\\[/tex]

Thermal Efficiency

[tex]u_{C} = 1- \frac{q_{c}}{q_{b}}\\\\u_{C} = 1 - \frac{1081}{1644.2}\\\\u_{C} =0.343[/tex]

Net work output

[tex]w_{C} = q_{b}-q_{c}\\w_{C} = 1644.2-1081\\\\w_{C}=563.2KJ/kg[/tex]

Answer: attached below. rate brainliest if correct please

Answer:

v = 1779 veh/h

Explanation:

We will calculate the peak hour volume by using the following formula:-

Vp = v / ( PHF)(N)(Fg)(Fhv)

here,

1. v is the peak hour volume

2. vp is the analysis flow rate

3. PHF is the peak hour factor

4. N is the number of lanes

5. Fg is the grade adjustment factor which is 0.99 for rolling terrain > 1200 pc/h/ln

6. Fhv is the heavy vehicle adjustment factor

vp = v / (PHF) (N) (Fg) (Fhv)

1250 = v / (0.84)(2)(1)(0.847)

v = 1779 veh/h

Answer:

V = 56.8 mV

Explanation:

When a current I flows across a circuit element, if we assume that the dimensions of the circuit are much less than the wavelength of the power source creating this current, there exists a fixed relationship between the power dissipated in the circuit element, the current I and the voltage V across it, as follows:

P = V*I

By definition, power is the rate of change of energy, and current, the rate of change of the charge Q, so we can replace P and I, as follows:

E/t = V*q/t ⇒ E = V*Q

Solving for V:

V = E/Q = 94.2 mJ /1.66 C = 56.8 mV

Answer:

The Java code is given below with appropriate variable names and tags for better understanding

Explanation:

import java.util.Scanner;

public class LabProgram{

   public static void main(String[] args) {

       Scanner scnr = new Scanner(System.in);

       int highwayNumber;

       int primaryNumber;

       highwayNumber = scnr.nextInt();

       if(highwayNumber<1 || highwayNumber>999)

           System.out.println(highwayNumber+" is not a valid interstate highway number.");

       else{

           if(highwayNumber>=1 && highwayNumber<=99){

               System.out.print("The "+highwayNumber+" is primary, going ");

               if(highwayNumber%2==1)

                   System.out.println("north/south.");

               else

                   System.out.println("east/west.");

           }

           else{

               primaryNumber = highwayNumber%100;

               System.out.print("The "+highwayNumber+" is auxillary, serving the "+primaryNumber+", going ");

               if(primaryNumber%2==1)

                   System.out.println("north/south.");

               else

                   System.out.println("east/west.");

           }

       }

   }

}

The program is an illustration of conditional statements.

Conditional statements are statements whose execution is dependent on its truth value.

The missing code segment in Java where comments are used to explain each line is as follows:

import java.util.Scanner;

public class Main {

   public static void main(String [] args){  

       Scanner scnr = new Scanner(System.in);  

       int highwayNumber; int primaryNumber;

       highwayNumber = scnr.nextInt();

       //This checks if the highwayNumber is not between 1 and 999 (inclusive)

       if (highwayNumber <1 || highwayNumber > 999){

           //If yes, the highwayNumber is invalid

           System.out.print(highwayNumber+" is not a valid interstate highwayNumber number.");

       }

       //If otherwise

       else{

           //This checks if highwayNumber is less than 100

           if (highwayNumber< 100){

               if (highwayNumber%2 == 0){

                   //Even highwayNumber are primary going east/west

                   System.out.print("I-"+highwayNumber+" is primary, going east/west.");

               }

           else{

               //Odd highwayNumber are primary going north/south

               System.out.print("I-"+highwayNumber+" is primary, going north/south.");

           }

           }

           //Otherwise

           else{

               if ((highwayNumber%100) % 2 == 0){

                   //Even highwayNumber are auxiliary going east/west

                   System.out.print("I-"+highwayNumber+" is auxiliary, going east/west.");

               }

               else{

                   //Even highwayNumber are auxiliary going north/south

                   System.out.print("I-"+highwayNumber+" is auxiliary, going north/south.");

               }

           }

       }

   }

}

Read more about similar programs at:

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Answer:

(a) Mass flow rate is 2528.75 kg/min

(b) Molar flow rate is 458.1 mol/s

(c) Toulene is in-compressible at standard temperature and pressure

Explanation:

The volume flow rate of liquid toulene is given:

Volume Flow Rate = 175 m^3/h

Density of Liquid Toulene = 867 kg/m^3

Molar mass of Toulene = 92 g/mol = 0.092 kg/mol)

(a)

Thus, the mass flow rate of toulene will be:

Mass Flow Rate = (Volume Flow Rate)(Density)

Mass Flow Rate = (175 m^3/h)(867 kg/m^3)

Mass Flow Rate = (151725 kg/h)(1 h/60 min)

Mass Flow Rate = 2528.75 kg/min

(b)

Now, for molar flow rate we use formula:

Molar Flow Rate = (Mass Flow Rate)/(Molar Mass)

Molar Flow Rate = (2528.75 kg/min)/(0.092 kg/mol)

Molar Flow Rate = (27486.41 mol/min)(1 min/60sec)

Molar Flow Rate = 458.1 mol/s

(b)

The assumption is that Toulene is in-compressible at standard temperature and pressure. So, that its density can be taken constant.

Answer:

(a) Aluminum Indium Gallium Phosphide (AlInGaP). Band gap = 1.81eV  ≈ 2eV

(b) Gallium Nitride (GaN). Band Gap = 3.4eV

(c) Aluminium Gallium Arsenide (AlGaA). Band Gap = 1.42eV ≈ 2.16eV

(d) Zinc Selenide (ZnSe). Band Gap = 2.82eV

(e) Gallium Phosphide (GaP). Band Gap = 2.24eV

Explanation:

LED's are semi-conducting materials that convert electrical energy to light energy. The light color emitted from the LED depends on the semi-conducting material and other compositions.

The band gap of the semi-conductor determines its wavelength. High band gap semi-conductors emit lower wavelengths which means greater power(UV semi-conducting macterials fall under this category).

Answer:

Integrity: involves maintaining and assuring the accuracy of data over its life-cycle

Explanation:

Confidentiality: This is a CIA triad designed to prevent sensitive information from reaching the wrong people, while making sure that the right people have access to it.

Integrity: This is a CIA triad that involves maintaining the consistency, accuracy, and trustworthiness of data over its entire life cycle.

Availability: This is a CIA triad that involves hardware repairs and maintaining a correctly functioning operating system environment that is free of software conflicts.

Authentication:This is a security control that is used to protect the system with regard to the CIA properties.

Answer:

Program comments

Answer:

[tex] \mu= \frac{1.2 lb ft}{7.85ft^2 * \frac{6.545 ft/s}{0.00292ft} *0.25 ft}=2.728x10^{-4} \frac{lbf s}{ft^2}[/tex]

Explanation:

For this case we need to remember first thet the torque T is defined as:

[tex] T = FR[/tex]

Where T represent the torque, F the force acting in the inner cylinder and R the radius for the inner cylinder.

For the inner cylinder the force acting can be expressed as:

[tex] F = \mu A \frac{v}{l}[/tex]

Where [tex] \mu[/tex] represent the viscosity of the fluid, A the area of the inner cylinder, v represent the tangential velocity and l the thickness of fluid between the two cylinders.

And the tangential velocity for this case can be esxpressed as [tex] v = wR[/tex]

The info given is:

[tex] l = 0.035 in *\frac{1ft}{12in}=0.00292 ft[/tex]

[tex] R= \frac{D}{2} =\frac{6 in}{2}= 3 in*\frac{1ft}{12 in}=0.25 ft[/tex]

[tex] L = 5 ft[/tex] from the info given

N= 250 rpm represent the reveolutions per minute

[tex] T = 1.2 lbf ft[/tex] represent the torque given

We can find the surface area for the cylinder with this formula:

[tex] A= 2\pi R L[/tex]

And if we replace we got:

[tex] A= 2\pi 0.25 ft *5 ft= 7.85 ft^2[/tex]

Now we can find the tangential velocity like this:

[tex] v=wR= \frac2\pi *250 rpm* \frac{1min}{60s} * 0.25 ft=6.55\frac{ft}{s}[/tex]

Now we can set up the following equation for the torque:

[tex] T = FR[/tex]

[tex] T = \mu A \frac{v}{l} R[/tex]

And we can find the value for the viscosity [tex]\mu[/tex] like this:

[tex] \mu = \frac{T}{A \frac{v}{l} R}[/tex]

And if we replace we got:

[tex] \mu= \frac{1.2 lb ft}{7.85ft^2 * \frac{6.545 ft/s}{0.00292ft} *0.25 ft}=2.728x10^{-4} \frac{lbf s}{ft^2}[/tex]

Answer:

in situ treatment would be better if; (1) a large volume of soil is to be treated at once, and (2) a permeable sandy soil (un-compacted) is to be treated.

ex situ treatment would be better would be better if; (1) a wider range of contaminants and soil types are to be treated, and (2) there is more certainty about the uniformity of treatment because of the ability to homogenize, screen, and continuously mix the soil.

Explanation:

in situ treatment would be better if;

ex situ treatment would be better would be better if;

Answer: c. Fully actuated

Explanation: fully actuated signals are completely influenced by volumes if traffic and employs sensors at all approaches for its detection.

Answer: 62 cos(50t - 70°)

Explanation:

First we need to convert all sines into cosines because phasor forms are represented through cosine. For that we will use the fact that sin(wt + ∅) = cos(wt + ∅ - 90°)

Therefore, 37sin50t = 37cos(50t - 90°)

Now we have 37cos(50t - 90°)+ 30 cos(50t – 45°). We need to convert them into phasor form to add the terms. For that we will use the fact Acos(wt+∅)=A∠∅ which can be represented using real and imaginary parts as A [cos(∅)+jsin(∅)].

So,

37cos(50t - 90°)

= 37∠-90°

= 37[cos(-90°)+jsin(-90°)

=37[0+j(-1)]

= -j37

Similarly,

30 cos(50t – 45°)

=30∠-45

=30[cos(-45)+jsin(-45)

=30[0.707-j0.707]

=21.21 - j21.21

37cos(50t - 90)+ 30 cos(50t – 45°) = -j37+21.21 - j21.21 = 21.21 - j58.21

Now we need to convert the real and imaginary parts back to cosine form. We will first calculate the magnitude by the formula √a²+b² where a and b are the real and imaginary parts respectively.

Here a=21.21 and b=58.21

magnitude = √(21.21)²+(58.21)²=61.95≅62

For calculating phase ∅ the formula is ∅=inversetan (b/a) where a and b are the real and imaginary parts respectively.

∅=inversetan(-58.21/21.21)

= -69.9°≅-70°

So the final answer is 62cos(50t-70°)

The value of [tex]\(37 \sin 50t + 30 \cos(50t - 45^\circ)\)[/tex] is [tex]\(61.97 \cos(50t - 70^\circ)\)[/tex].

To solve [tex]\(37 \sin 50t + 30 \cos(50t - 45^\circ)\)[/tex] using phasors, we follow these steps:

Step-by-Step Calculation:

1. Express each term as a phasor:

- The term [tex]\(37 \sin 50t\)[/tex] :

    - Convert to cosine form: [tex]\(37 \sin 50t = 37 \cos(50t - 90^\circ)\)[/tex]

    - Phasor form: [tex]\(37 \angle -90^\circ\)[/tex]

  - The term [tex]\(30 \cos(50t - 45^\circ)\)[/tex] :

    - Phasor form: [tex]\(30 \angle -45^\circ\)[/tex]

2. Convert the phasors to rectangular form:

  - [tex]\(37 \angle -90^\circ\)[/tex] :

    [tex]\[ 37 \cos(-90^\circ) + j 37 \sin(-90^\circ) = 0 - j 37 = -j 37 \][/tex]

- [tex]\(30 \angle -45^\circ\)[/tex]:

    [tex]\[ 30 \cos(-45^\circ) + j 30 \sin(-45^\circ) = 30 \left(\frac{\sqrt{2}}{2}\right) - j 30 \left(\frac{\sqrt{2}}{2}\right) = 21.2132 - j 21.2132 \][/tex]

3. Add the rectangular components:

 [tex]\[ -j 37 + (21.2132 - j 21.2132) \][/tex][tex]\[ = 21.2132 - j (37 + 21.2132) \][/tex]

  [tex]\[ = 21.2132 - j 58.2132 \][/tex]

4. Convert the result back to polar form:

  - Magnitude:

   [tex]\[ R = \sqrt{21.2132^2 + 58.2132^2} = \sqrt{449.54 + 3388.78} = \sqrt{3838.32} = 61.97 \][/tex]

  - Angle:

   [tex]\[ \theta = \tan^{-1}\left(\frac{-58.2132}{21.2132}\right) = \tan^{-1}(-2.743) \approx -70^\circ \][/tex]

5. Express the final result:

  Using the positive magnitude, the expression in cosine form is:

  [tex]\[ 37 \sin 50t + 30 \cos(50t - 45^\circ) = 61.97 \cos(50t - 70^\circ) \][/tex]

Answer: 30joules

Explanation

voltage of battery =12volts

2.5coulombs is the same as 2.5ampere-seconds

Energy required =12V*2.5A-S

=30watts-seconds

Hence the required energy is equal to 30joules.

Answer:

a) 0.759 m , 0.759 m

b) 10.1 m , 10.3 m

c) 12.3 m , 13 m

Explanation:

Vapour Pressure included:

[tex]P_{atm,vp} = y*h + P_{vp} \\\\h = \frac{P_{atm,vp}-P_{vp}}{y} ... Eq1[/tex]

mercury

[tex]h_{Hg,vp} = \frac{101*10^3-1.6*10^(-1)}{133*10^3} \\\\h_{Hg,vp} = 0.759m[/tex]

[tex]h_{Hg} = \frac{101*10^3}{133*10^3} \\\\h_{Hg} = 0.759m[/tex]

water

[tex]h_{H2O,vp} = \frac{101*10^3-1.77*10^3}{9.8*10^3} \\\\h_{H2O,vp} = 10.1m[/tex]

[tex]h_{H2O} = \frac{101*10^3}{9.8*10^3} \\\\h_{H20} = 10.3m[/tex]

Ethyl Alcohol

[tex]h_{EA,vp} = \frac{101*10^3-5.9*10^3}{7.74*10^3} \\\\h_{EA,vp} = 12.3m[/tex]

[tex]h_{EA} = \frac{101*10^3-5}{7.74*10^3} \\\\h_{EA} = 13m[/tex]

For mercury barometers the effects of vapour pressure are negligible and required height for mercury barometer is reasonable as compared to that of water and ethyl alcohol.

The time that the maximum queue length occurs would be c. 49.4 min

To find the time at which the maximum queue length occurs, we need to determine when the arrival rate equals the departure rate.

The queue length increases when the arrival rate exceeds the departure rate and decreases when the departure rate exceeds the arrival rate. The maximum queue length occurs when the arrival rate equals the departure rate.

Substituting the given functions into the equation, we get:

[tex]\[ 1.8 + 0.25t - 0.0030t^2 = 1.4 + 0.11t \][/tex]

Rearranging the terms, we get a quadratic equation:

[tex]\[ -0.0030t^2 + 0.25t - 0.11t + 1.8 - 1.4 = 0 \][/tex]

[tex]\[ -0.0030t^2 + 0.14t + 0.4 = 0 \][/tex]

Now, we can solve this quadratic equation to find the value(s) of t at which the maximum queue length occurs. We can use the quadratic formula:

[tex]\[ t = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a} \][/tex]

Where:

a = -0.0030

b = 0.14

c = 0.4

Calculate the values of t using this formula. Then, we'll choose the appropriate value based on the physical meaning of the problem.

Using the quadratic formula:

[tex]\[ t = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a} \][/tex]

[tex]\[ t = \frac{-0.14 \pm \sqrt{(0.14)^2 - 4(-0.0030)(0.4)}}{2(-0.0030)} \][/tex]

[tex]\[ t = \frac{-0.14 \pm \sqrt{0.0196 + 0.0048}}{-0.0060} \][/tex]

[tex]\[ t = \frac{-0.14 \pm 0.156}{-0.0060} \][/tex]

Now, we have two possible values for t :

1. [tex]\( t_1 = \frac{-0.14 + 0.156}{-0.0060} \)[/tex]

2. [tex]\( t_2 = \frac{-0.14 - 0.156}{-0.0060} \)[/tex]

Calculate these values:

1. [tex]\( t_1 = \frac{0.016}{-0.0060} = -2.67 \)[/tex]

2. [tex]\( t_2 = \frac{-0.296}{-0.0060} = 49.4[/tex]

Since t represents time, it cannot be negative. The maximum queue length occurs at approximately t = 49.4 minutes after the beginning of the observation.

Answer:

Tempered glass

Explanation:

Tempered or toughened glass is a type of safety glass processed by controlled

thermal or chemical treatments to increase its strength compared with normal glass. Tempering puts the outer surfaces into compression and the interior into tension . Such stresses cause the glass, when broken, to crumble into small granular chunks instead of splintering into jagged shards as plate glass (a.k.a. annealed glass) does. The granular chunks are less likely to cause injury.

Answer: tempered glass

The characteristics listed in the options are the characteristics of an insulating glass, a type of glass with double or more panes used to reduce heat loss within a building.

Explanation:

A tempered glass is also known as a toughened glass. It is a type of glass that is produced through controlled thermal or chemical treatment which helps to increase its quality in terms of toughness. A tempered glass is a safety glass and as a result of this, its surface is four times toughened than that of a normal glass.

The temperature at which the resistance is [tex]1 k\Omega[/tex] is [tex]89.4^{\circ}C[/tex]

Explanation:

For the thermistor in this problem, the relationship between temperature and resistance is linear.

We have:

[tex]R_1 = 5000 \Omega[/tex] when the temperature is [tex]T=25^{\circ}C[/tex]

[tex]R_2=340 \Omega[/tex] when the temperature is [tex]T=100^{\circ}C[/tex]

Assuming a straight-line relationship, we can find the slope of the line:

[tex]m=\frac{R_2-R_1}{T_2-T_1}=\frac{340-5000}{100-25}=-62.1 \Omega/^{\circ}C[/tex]

Now that we know the slope, we can extrapolate the temperature when the resistance is

[tex]R_3 = 1 k\Omega = 1000 \Omega[/tex]

In fact, we can write:

[tex]m=\frac{R_3-R_2}{T_3-T_2}[/tex]

And solving for [tex]T_3[/tex],

[tex]m(T_3-T_2)=R_3-R_2\\T_3 = T_2 +\frac{R_3-R_2}{m}=100 + \frac{1000-340}{-62.1}=89.4^{\circ}C[/tex]

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The temperature at which the thermistor's resistance equals 1 kΩ is approximately 11.88 °C.

The relationship between the resistance of a thermistor and temperature can be modeled by a straight line equation, which is given by:

R = Ro(1 + αΔT)

where R is the resistance at a given temperature, Ro is the resistance at a reference temperature, α is the temperature coefficient of resistance, and ΔT is the change in temperature from the reference temperature.

To find the temperature at which the thermistor's resistance equals 1 kΩ, we can rearrange the equation:

ΔT = (R/Ro - 1) / α

Plugging in the given values:

Ro = 5 kΩ, R = 1 kΩ, α = (340 Ω - 5 kΩ) / (100 °C - 25 °C)

ΔT = (1 kΩ / 5 kΩ - 1) / [(340 Ω - 5 kΩ) / (100 °C - 25 °C)]

Simplifying the equation, we find that ΔT ≈ -14.12 °C.

Therefore, the temperature at which the thermistor's resistance equals 1 kΩ is approximately 11.88 °C.

Answer:

Answer  of the Java class explained below with appropriate comments

Explanation:

using System;

class MainClass {

 public static void Main (string[] args) {

//entering wind speed of the hurricane

   Console.WriteLine ("Enter wind speed in mph: ");

   int windSpeed = Convert.ToInt32(Console.ReadLine());

//checking for the category with the credited wind speed

   int category = GetCategory(windSpeed);

   Console.WriteLine ("Category: " + category);

 }

 public static int GetCategory(int wind) {

     //function for classifying the wind speeds

     if(wind >= 157) {

     return 5;

     }

     if(wind >= 130) {

         return 4;

     }

     if(wind >= 111) {

         return 3;

     }

     if(wind >= 96) {

         return 2 ;

     }

     return 1;

 }

}

Answer:

a) 6.4  mg/l

b) 5.6 mg/l

Explanation:

Given data:

effluent Discharge Q_w = 1.0 m^3.s

Ultimate BOD L_w = 40 mg/l

Discharge of stream Q_r = 10 m^3.s

Stream ultimate BOD L_r = 3  mg/l

a) Ultimate BOD of mixture[tex] = \frac{Q_w l_w + Q_r L_r}{Q_w + Q_r}[/tex]

                                         [tex] = \frac{1*40 + 10*3}{10 +1} = 6.4 mg/l[/tex]

b) utlimate BOD at 10,000 m downstream

[tex]t =\frac{distance}{speed} = \frac{10,000}{\frac{Q_r +Q+w}{55}} \times \frac{hr}{3600} \times  \frac{day}{24 hr}[/tex]

putting [tex]Q_r + Q_w = 1+ 10 = 11 m^3/s[/tex]

t = 0.578  days

we know

[tex]L_t = L_o e^{-kt}[/tex]

[tex]L_t = 6.4 \times e^{-0.22 \times 0.578}[/tex]

[tex]L_t = 5.6 mg/l[/tex]

Answer:

c.attenuation

Explanation:

In telecommunication, it is called attenuation of a signal, be it acoustic, electrical or optical, to the loss of power suffered by it when passing through any transmission medium.

Attenuation is usually not expressed as a difference in powers but in logarithmic units such as decibels, which are more comfortable to use when calculating.

The attenuation is expressed in decibels (db) and the power is measured with this formula:

α = 10 * log (P1 / P2)

where P is the power both initial and final.

Answer:

sulfur dioxide

Explanation:

The scrubber is an apparatus installed in a coal-fired power plant to clean the passing gas through the smokestack.  Due to the norm enacted through the clean air Act, almost all the scrubber used in the U.S is used to remove sulfur concentration from coal. it can remove approx 90-95% SO_2 from the smokestack.

Answer:

sulfur dioxide.

Explanation:

Answer:

Fde = 1080 N (3 sig fig)

Explanation:

Taking point E

Sum of forces at E in x direction:

Fde cos (30) - Fcd = 0  ..... Eq 1

Sum of forces at E in y direction:

Fde sin (30) - Wf = 0   ..... Eq 2

Wf = m*g = 55 * 9.81 = 539.55 N

Using Eq 2 to evaluate Fde

Fde = Wf / sin (30) = 539.55 / sin (30) = 1079.1 N

Answer: Fde = 1080 N (3 sig fig)

The calculation of the exit temperature of water in the heated pipe involves using the energy balance equation, considering the heat lost through the pipe walls by convection, and then finding the change in thermal energy of the water via the heat transfer equation to solve for the exit temperature.

Exit Temperature of Water in a Heated Pipe

To determine the exit temperature of water at the end of an over-pressurized heated pipe, we must consider the energy balance for the water flowing through the pipe. Based on the first law of thermodynamics, the change in thermal energy of the water will be equal to the heat lost through the pipe walls by convection:

Q = mc_p
(Exit Temperature - Inlet Temperature)

In this case, Q will be negative, since the water is losing heat to the surrounding air. The heat transfer from the pipe to the air is given by:

Q = hA(T_surface - T_air)

The area A for heat transfer is the external surface area of the pipe (
2
classes Math.PI
* radius * length of the pipe). Since we have the heat transfer coefficient h, the surface temperature of the pipe T_surface, and the air temperature T_air, we can calculate Q. Then we can use the mass flow rate m and the constant pressure specific heat c_p to find the exit temperature of the water.

To solve, we first calculate Q, then rearrange the first equation to solve for the Exit Temperature.

Answer:

Part A:

In W-h:

Energy Stored=1440 W-h

In Joules:

[tex]Energy Stored=5.184*10^6Joules\\Energy Stored=5.184 MJ[/tex]

Part B:

In W-h:

Energy left=240 W-h

In Joules:

Energy left= 8.64*10^5 J

Explanation:

Part A:

We are given rating 120A-h and voltage 12 V

Energy Stored= Rating*Voltage              (Gives us units W-h)

Energy Stored=120A-h*12V

Energy Stored=1440 W-h

Converting it into joules (watt=joules/sec)

Energy Stored=[tex]1440 Joules * \frac{3600sec}{h}h[/tex]

Energy Stored=5184000 Joules

[tex]Energy Stored=5.184*10^6Joules\\Energy Stored=5.184 MJ[/tex]

Part B:

Energy used by lights for 8h=150*8

Energy used by lights for 8h=1200W-h

Energy left= Energy Stored(Calculated above)- Energy used by lights for 8h

Energy left=1440-1200

Energy left=240 W-h

Energy left=[tex]240 Joules * \frac{3600sec}{h}h[/tex]

Energy left=864000 Joules

Energy left= 8.64*10^5 J

The total energy stored in the battery is 1440 Wh. If the headlights are left on overnight (8h), the energy remaining in the battery in the morning is 1320 Wh.

(a) The total energy stored in the battery can be calculated by multiplying the battery's capacity (120 A-h) by the voltage (12 V). So, the total energy stored in the battery is 1440 Wh.

(b) To calculate the energy consumed by the headlights in 8 hours, we need to find the power (P) using the formula P = V × I, where V is the voltage (12 V) and I is the current (the total power rating divided by the voltage). Then, we can find the energy consumed by multiplying the power by the time (8 hours). We can subtract this energy consumption from the total energy stored in the battery to find the energy remaining in the morning. So, the energy remaining in the battery is 1440 Wh - 12 kWh = 1320 Wh.

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Answer:

I am writing a function in C++                              

Explanation:

#include <iostream>

using namespace std;

int pyramid(int height) // function pyramid with parameter height

{int distance; //variable for spaces

   for(int i = 1, j = 0; i <= height; ++i, j= 0)  //handle the rows

   {

for(distance= 1; distance<= height-i; ++distance)

// handles the spaces & columns

    { cout <<"  ";        } //prints spaces between stars

       while(j!= 2*i-1)  //handles shape and spaces

       {   cout << "* "; // printing stars

           ++j;        }

       cout << '\n';    }   } // for the next line

int main()

{

int height; //declare height variable

cout <<"Enter height of pyramid "; //asks user to enter height of pyramid

cin>>height; //stores value of height

pyramid(height); //calls pyramid function

}