HNCB3 | Building Mathematics | Mathematics

TASK 1

Scenario 1

 You have been contracted as a mathematical consultant to solve and confirm a number of mathematical problems/solutions for projects on a major contract

1. A building services engineer is to design a water tank for a project. The tank has a rectangular area of 26.5m². With the design specifics of the width being 3.2m shorter than the length, calculate the length and width to 3 significant figures for resource requirements (P1)

2. As an employee of company JR construction you have received a letter regarding the project your company is working on. It has a penalty clause that states the contactor will forfeit a certain some of money each day for late completion. (i.e. the contractor gets paid the value of the original contract less any sum forfeit). If she is 5 days late she receives £4250 and if sheis 12 days late she receives £2120. Calculate the daily forfeit and determine the original contract (P2)

Scenario 2

 You have asked to convert various dimensional parameters using the following table

A car driving at an average speed 65 miles/hour (note 1 mile=1760 yards)

Calculate : (a)

speed in meters/second

How long will it take to drive 100miles

The car’s fuel consumption averages 30miles/gallon convert this to liters/kilometer

How much fuel is required in liters for the journey

(P1)

(b)

Determine the units of the lift produced by an aircraft wing. The lift is directly proportional the product of the air density, the air speed over the wing and the surface area of the wing (MERIT M1))

Lift    k            V ²   A

A      Area of the wing in meter²

Air density in Kg/meter³ A Area of the wing

k has no dimensions

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Scenario 3

You have asked to investigate the following arithmetic sequences

1. An arithmetic sequence is given by b, ²₃^b , ^b₃ , 0.......

 Determine the sixth term State the k^th term

 If the 20^th term has value of 15 find the value of b and the sum of the first 20 terms (P2)

2. For the following geometric progression 1, ¹₂ , ¹₄ ........ determine The 20^th term of the progression

The value of the sum when the number of terms in the sequence tends to infinity and explain why

n

the sequence tends to this value S _n             arⁿ   (P2)

n  0

3. Solve the following Equations for x :

• 2Log (3x) + Log (18x) = 27

(b)              2LOGe(3x) + LOGe(18x) = 9                                                                      (P3)

• Solve the following Hyperbolic Equations for the variables involved:
• Cosh(X) + Sinh(X) = 5
• Cosh(2Y) - Sinh(2Y) = 3
• Cosh(K) * Sinh(K) = 2
• Cosh(M) / Sinh(M) = HNC/HND Construction and the Built Environment      4

L02 Investigate applications of statistical techniques to interpret, organise and present data by using appropriate computer software packages

TASK 2

Scenario 1

You have been asked to investigate the following data for  a large  building services company

Revenue	Number of customers
	Number of customers
	January	July
Less than 5	27	22
5 and less than 10	38	39
10 and less than 15	40	69
15 and less than 20	22	41
20 and less than 30	13	20
30 and less than 40	4	5

1. Produce a histogram for each of the distributions scaled such that the area of each rectangle represents frequency density and find the mode. (D1)
2. Produce a cumulative frequency curve for each of the distributions and find the median, and interquartile range (D1)
3. For each distribution find the: the mean the range

the standard deviation

(P4)

Scenario 2

• In the new Epiphyte Engineering factory 5000 light bulbs Type A are installed. Their lengths of life are normally distributed with a mean of 360 days and a standard deviation of 60 days.

1. How could the assumption that the bulb life is a normal distribution be tested?

1. If it is decided to replace all bulbs at one specified time, what interval must be allowed between replacements if not more than 10% of bulbs should fail before replacement?

1. What practical considerations might dictate such a replacement policy?

1. The supplier offers a new type of bulb, Type B, that has a mean life of 450 days and the same standard deviation (60 days) as the present type. If these bulbs were to be used how would the replacement time be affected?

1. Determine whether the new type of bulb is preferable given that is costs 25% more than the

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existing Type A. Present and explain your conclusions.

1. A rival supplier now offers a third type of bulb, Type C, that has a mean life of 432 days and a standard deviation of 45 days. If these bulbs were to be used how would the replacement time be affected?

How should the Type C bulb compare for costs if it is to be adopted? Present and explain your conclusion (P5)

• A simple random sample of 10 people from a certain population has a mean age of 27 years. Can we conclude that the mean age of the population is not 30 years? The variance of the populate ages is known to be 20. Test your chosen hypothesis at a 5% level of significance using both a two tailed test and a one tailed test and explain your conclusions. (M2)

 L03 Use analytical and computational methods for solving problems by relating sinusoidal wave and vector functions to their respective construction applications

 TASK 3

 Scenario 1

 A support beam, within an industrial building, is subjected to vibrations along its length; emanating from two machines situated at opposite ends of the beam. The displacement caused by the vibrations can be modelled by the following equations,

2

₁ = 3.75sin (100     + ₉ )

2

₂ = 4.42sin (100     − ₅ )

1. State the amplitude, phase, frequency and periodic time of each of these waves. (P6)

1. When both machines are switched on, how many seconds does it take for each machine to produce its maximum displacement? (P6)

• At what time does each vibration first reach a displacement of −2 ? (P6)

1. Use the compound angle formulae to expand ₁ and ₂ into the form sin100 ± cos 100    , where and are numbers to be found. (M3)

1. Using your answers from part iv, express ₁ + ₂ in a similar form. Convert this expression into the

sin(100     +   ).(M3)equivalentform

1. Using appropriate spread sheet software, copy and complete the following table of values: (D2)

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0.000

0.002

0.004

0.006

0.008

0.010

0.012

0.014

0.016

0.018

0.020

• Plot the graphs of ₁ and ₂ on the same axes using any suitable computer package or otherwise. Extend your table to include ₁ + ₂ and plot this graph on the same axes as the previous two. State the amplitude and frequency of the new wave. (D2)
• Using your answers from parts v and vii, what conclusions can be drawn about ₁ + ₂ and the two methods that were used to obtain this information? (D2)

 Scenario 2

 A pipeline is to be fitted under a road and can be represented on 3D Cartesian axes as below, with the - axis pointing East, the -axis North, and the -axis vertical. The pipeline is to consist of a straight section directly under the road, and another straight section connected to the first. All lengths are in metres.

1. Calculate the distance.

The section         is to be drilled in the direction of the vector 3  + 4  +                                         .

1. Find the angle between the sectionsand.

The section of pipe reaches ground level at the point  ( ,  , 0).

• Write down a vector equation of the line. Hence find and  . (P7)

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TASK 4

L04 Illustrate the wide-ranging uses of calculus within different construction disciplines by solving problems of differential and integral calculus

SCENARIO 1

You have asked to investigate the following :

(a i)

Plot the bending moment and determine where the bending moment is zero (P9)

(a ii) Investigate and state the range of values where the above Bending Moment Function ls maximum or Minimum, decreasing or increasing or neither.

(b)Determine the range of the temperature for positive t  (P9)

• Note that in the thermodynamic system provided herein, the expression given is equated to 0 to solve the problem given to be solved. (P8):

Also determine the rate of change of V when P changes at regular intervals of 10 N/mm2 from 60 to 100N/m2 and the variable n=2. (P8)

Scenario 2

Righton Refrigeration specialises in the production of environmental engineering equipment. The cost of manufacture for a particular component, £C, is related to the production time (t)minutes, by the following formula

 C=16t^-2+2t^-

 Investigate the variation of cost over a range of production times from 1 minute to 8 minutes:

1. Plot the cost function over the given range

1. Explain how calculus may be used to find an analytical solution to this problem of optimisation.

1. Use calculus to find the production time at which the cost is at a turning point.

1. Show that the turning point is a mathematical minimum.

Discuss whether there would still be a minimum cost of production.    (D3)

 Scenario 3

 The heat flow within a building is increasing or decreasing exponentially E to power 3t in line with temperature difference which is t degrees ( C) with the outside surroundings.

 Estimate and explore the growth rate graphically when the temperature difference changes from - 20degrees to + 20 degrees (C) (M4)

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Learning Outcomes and Assessment Criteria

		Pass			Merit			Distinction
		LO1 Identify the relevance of mathematical methods to a variety of conceptualised
		construction examples
								D1 Present statistical data in a
		P1 Apply dimensional analysis techniques			M1 Apply dimensional analysis to derive
								method that can be understood by
		to solve complex problems.			equations
								a non - technical audience.
		P2 Generate answers from contextualised
		arithmetic and geometric progressions.
		P3 Determine the solutions of equations
		using exponential, trigonometric and
		hyperbolic functions.
		LO2 Investigate applications of statistical techniques to interpret, organise and present
		data by using appropriate computer software packages
		P4 Summarise data by calculating mean			M2 Interpret the results of a statistical
		and standard deviation, and simplify data			hypothesis test conducted from a given
		into graphical form.			scenario.
		P5 Calculate probabilities within both
		binomially distributed and normally
		distributed random variables.
		LO3 Use analytical and computational methods for solving problems by relating						D2 Model the combination of sine
		sinusoidal wave and vector functions to their respective construction applications.						waves graphically and analyse the
								variation between graphical and
		P6 Solve construction problems relating to			M3 Apply compound angle identities to			analytical methods.
		sinusoidal functions.			separate waves into distinct component
		P7 Represent construction quantities in			waves.
		vector form, and apply appropriate
		methodology to determine construction
		parameters.
		LO4 Illustrate the wide -ranging uses of calculus within different construction
		disciplines by solving problems of differential and integral calculus						D3 Analyse maxima and minima of
								increasing and decreasing
		P8 Determine rates of change for		M4 Formulate predictions of exponential
								functions using higher order
		algebraic, logarithmic and circular		growth and decay models using
								derivatives.
		functions.		integration methods.
		P9 Use integral calculus to solve practical
		problems relating to engineering.