matt purchased a 20 year par value bond with 8 semiannual coupon at a price of 1772.25. The bond can be called at par value X on any coupon date startinga t the end of year 15. The price guarantees that Matt will receive a nominal semiannual yield of at least 6%. Bert purchases a 20-year par value bond identical to the one purchased by Matt, eexcept that it is not callable. Assume a nominal semiannual yield of 6%, the cost of the bond puirchased by Bert is P. Calculate P.

Answer:

Step 1

Let us assume that x1 amount of Fliptop and x2 amount of Tiptop models are produced, then the objective function is to maximize profitability with the constraints on the production limited by the available plastic, ink and time. Hence the LP model is given by the objective function and the three constraints as shown below:

Objective function ($) (OF):                maximize z = 1000x1 + 1000x2

Plastic material constraint ( Eqn. 1): 3x1 + 4x2 <= 36

Ink material constraint (Eqn. 2):         5x1 + 4x2 <= 40

Time constraint (Eqn. 3):                    5x1 + 2x2 <= 30

Non negativity constraints:                 x1, x2 >= 0

Step 2

Since it is a 2 variable problem it can be solved graphically or using a model solver such as MS-Excel ®. The feasible region is defined by the corner points (boundary points) A, B, C, D, E and the boundary lines of the constraint equations 1,2,3 and the objective function OF as shown in the diagram.

The coordinates and the OF values at the corner points are given below:

A (0,0); OF = 0 (intersection of non-negativity constraints)

B (6,0); OF = 6000 (intersection of x2=0 and eqn 3)

C (4,5); OF = 9000 (intersection of eqn 2 and 3)

D (2, 7.5); OF = 9500 (intersection of eqn 1 & 2)

E (0,9); OF= 9000 (intersection of x1=0 and eqn 1)

Step 3

Hence the optimal solution is given by the point D where the OF equation touches the feasible region with the maximum value. There is an excess of 5 units of molding time available.

The linear programming model for this problem is to maximize profit while considering the constraints. The optimal solution can be found using graphical or algebraic methods. Slack variables can be used to determine if there will be excess capacity in any resource.

The linear programming model for this problem can be represented as follows:

Subject to:

To find the optimal solution, we can use graphical or algebraic methods. By solving this linear programming problem, we can determine the optimal values for X and Y, which will maximize the profit.

To determine if there will be excess capacity in any resource, we need to calculate the slack variables for each constraint. If the slack variable is greater than zero, it indicates that there is excess capacity for that resource.

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Answer:

Average receivables = $157,500,000

Explanation:

Account receivable represent the amount of credit made by a business which remain uncollected as at the reporting date. In other words, they represent the amount that customers are owing the business in respect of credit sales.

Average account receivables

=(opening balance + closing balance)/2

=( $142,650,000 + $172,350,000)/2

= 157,500,000.

Answer:

13.856%

Explanation:

For computing the discounting rate we have to find out the weightage average cost of capital but before that first we have to determine the cost of equity and the after tax cost of debt which is shown below:

Cost of equity = Risk free rate of return + Beta × market risk premium

= 8% + 2 × 4%

= 16%

And, the after cost of debt is

= Cost of debt × ( 1 - tax rate)

= 8% × (1 - 0.34)

= 5.28%

Now the weighted cost of capital is

= Cost of debt × weighted of debt + cost of equity × weighted of equity

= 5.28% × 20% + 16% × 80%

= 1.056% + 12.8%

= 13.856%

Answer:

38880

Explanation:

Budgeted sales -870 boxes

Each box requires 44 pounds of clay

Opening inventory of clay = 3900 pounds

Closing inventory of clay = 4500 pounds

Clay mix cost - $0.40

Labor rate = $12/hr

Monthly purchase = budgeted sales  + closing inventory - opening inventory

(870*44) + 3900 - 4500

38280 +4500 - 3900 = 38,880

Answer:

This is correct, along with some other things a project manager could do.

Explanation:

Answer:  1.project

                2.communication

Explanation:

got it right on plato/edmentum ;)

Answer:

Payback period= 2 years, 7.53 months

If Susan assigns a 3 year payback period, the toys should  be added.

This is so because, with a 3 year payback period, Susan would expect to recoup her investment within a three year period but the project would actually recoup its cash outflow in less than 3 years.

Since the actual payback period(2 year 7.5 months) is less than the target payback period (3 years), the investment should be undertaken

Explanation:

The payback period is the estimated length of time in years it takes  

the net cash inflow from a project to equate the net cash the initial cost

The total cost of the investment =6,500+2,800 = 9300

Payback period

Cumulative cash inflow at the end of year two= 3,300+ $3,300= 6600

Balance left to recoup investment = 9,300 - 6,600 = 2,700

Payback period = 2 years + (2700/4300)× 12

                          = 2 years, 7.53 months

If Susan assigns a 3-year payback period, the toys should  be added.

This is so because, with a 3-year payback period, Susan would expect to recoup her investment within a three-year period but the project would actually recoup its cash outflow in less than 3 years.

Since the actual payback period(2 year 7.5 months) is less than the target payback period (3 years), the investment should be undertaken. Because the project would recoup its investment faster than than the stipulated time.

Answer:

2.63 years or 2 years 7.56 months

Explanation:

Payback period is the time in which a project returns back the initial investment in the form of net cash flow.

Initial Investment includes all the expense made on an asset to make it usable.

Initial Investment = $6,500 + $2,800 = $9,300

Year     Balance    Recovery    Time period

  0        ($9,300)          0                  0

  1         ($6,000)      $3,300             1

  2        ($2,700)      $3,300              1

  3         $1,600        $2,700           0.63

Total Period                                   2.63 years

Payaback period = 2 years + 0.63 x 12 months = 2 years 7.56 months              

Answer:

It is more convenient to produce in house, so the  Best Bicycles makes the part, its operating income will be $140,000  

Explanation:

Given the information:

The cost of producing 43,000 parts is $140,000 :

outside supplier for $3.80 per unit

avoid 30% of the fixed costs

As we know, the total costs if company bought is as following;

= Cost of production × Outside supplier per unit) + (Fixed cost × Remaining percentage)

= (43,000*$3.80 per unit)  + ($68,000*(100% - 30%))

= $163,400 + $47,600

= $211,000

=> the loss in income if the company decided to buy:

= the total costs if company bought - The cost of production

= $211,000 - $140,000

= $71,000

It is more convenient to produce in house, so the  Best Bicycles makes the part, its operating income will be $140,000  

Answer:

The answer is Lola should acknowledge a $3,000 from this distribution.

Explanation:

From the question given, we say that, Lola should acknowledge a $3,000 from this distribution.

Recall that

The Cash Distributed  cash = $ 25,000

The Basis in this ownership of interest is  = $22,000

The Gain = $3,000

Lola basis after the distribution is zero.

Therefore Lola should accept this distribution of a $ 3000

Answer: Please refer to Explanation

Explanation:

a) Equipment was purchased on the 1st of April meaning that it was used only 9 months in 20Y5.

The Straight line method of depreciation calls for a uniform depreciation throughout the life of the asset.

The formula is,

= (Cost - Salvage Value) / Years of service

= (52,000 - 3,000) / 10

= $4,900

However on the first year it was only used for 9 months so that has to be accounted for as,

= 4,900 * 9 months / 12 months

= $3,675

Depreciation in first year is $3,675

An entire year now (20Y6)

= (Cost - Salvage Value) / Years of service

= (52,000 - 3,000) / 10

= $4,900

Depreciation in 20Y6 is $4,900

b) Year 20Y5

The double-declining-balance method does not make use of the residual/scrap value and it goes at twice the rate of the Straight line method.

The formula is,

= (Cost - Accumulated Depreciation)/Years of service * 2

= (52,000 - 0)/ 10 * 2

= $10,400

Was used for 9 months so,

= 10,400 * 9 months / 12 months

= $7,800

Year 20Y6

= (Cost - Accumulated Depreciation)/Years of service * 2

= (52,000 - 7,800) / 10 * 2

= 4,420 * 2

= $8,840

Depreciation in 20Y6 using double declining method is $8,840

a. The depreciation for the current fiscal year by the straight-line method is $3,900 and for the following fiscal year is $9,000.

b. The depreciation for 20Y5 by the double-declining-balance method is $14,520 and for 20Y6 is $9,139.20.

a. Straight-Line Depreciation Method:

First, we calculate the total depreciable amount by subtracting the residual value from the cost of the equipment:[tex]\[ \text{Total Depreciable Amount} = \text{Cost} - \text{Residual Value} \] \[ \text{Total Depreciable Amount} = \$52,000 - \$3,000 = \$49,000 \][/tex]

Next, we determine the annual depreciation by dividing the total depreciable amount by the useful life:

[tex]\[ \text{Annual Depreciation} = \frac{\text{Total Depreciable Amount}}{\text{Useful Life}} \] \[ \text{Annual Depreciation} = \frac{\$49,000}{10} = \$4,900 \][/tex]

For the current fiscal year, since the equipment was placed into service on April 1, we prorate the annual depreciation based on the number of months in use:[tex]\[ \text{Current Year Depreciation} = \text{Annual Depreciation} \times \frac{\text{Months in Use}}{12} \] \[ \text{Current Year Depreciation} = \$4,900 \times \frac{9}{12} = \$3,675 \][/tex]

However, since the question asks for the depreciation for the current fiscal year, which ends on December 31, we must calculate for the full year, so the depreciation for the current fiscal year is the full annual depreciation:

[tex]\[ \text{Current Year Depreciation} = \$4,900 \][/tex]

For the following fiscal year, the depreciation will also be the full annual depreciation since the equipment will be in use for the entire year:

[tex]\[ \text{Following Year Depreciation} = \$4,900 \][/tex]

b. Double-Declining-Balance Depreciation Method:

First, we calculate the straight-line depreciation rate:

[tex]\[ \text{Straight-Line Rate} = \frac{1}{\text{Useful Life}} \] \[ \text{Straight-Line Rate} = \frac{1}{10} = 0.10 \][/tex]

Then, we double this rate to get the double-declining-balance rate:

[tex]\[ \text{Double-Declining Rate} = 2 \times \text{Straight-Line Rate} \] \[ \text{Double-Declining Rate} = 2 \times 0.10 = 0.20 \][/tex]

For 20Y5, we apply the double-declining rate to the remaining book value of the equipment. Since this is the first year of depreciation, the book value is the original cost minus the residual value:

[tex]\[ \text{Year 5 Depreciation} = \text{Book Value} \times \text{Double-Declining Rate} \] \[ \text{Year 5 Depreciation} = (\$52,000 - \$3,000) \times 0.20 = \$49,000 \times 0.20 = \$9,800 \][/tex]

For 20Y6, we first calculate the new book value by subtracting the depreciation taken in 20Y5 from the original book value:

[tex]\[ \text{New Book Value} = \text{Original Book Value} - \text{Year 5 Depreciation} \] \[ \text{New Book Value} = \$49,000 - \$9,800 = \$39,200 \] Then we apply the double-declining rate to this new book value: \[ \text{Year 6 Depreciation} = \text{New Book Value} \times \text{Double-Declining Rate} \] \[ \text{Year 6 Depreciation} = \$39,200 \times 0.20 = \$7,840 \][/tex]

However, we must ensure that the total depreciation does not exceed the total depreciable amount over the useful life. If the calculated depreciation for 20Y6 is more than the remaining depreciable amount, we adjust it to equal the remaining depreciable amount. The remaining depreciable amount after 20Y5 is:

[tex]\[ \text{Remaining Depreciable Amount} = \$49,000 - \$9,800 = \$39,200 \][/tex]

The depreciation for 20Y6 cannot exceed \$39,200. Since the calculated depreciation for 20Y6 (\$7,840) is less than the remaining depreciable amount, it is acceptable.

Finally, we round the depreciation for 20Y6 to the nearest cent:

[tex]\[ \text{Year 6 Depreciation} = \$7,840 \][/tex]

However, there seems to be an error in the calculation for 20Y6. The book value at the end of 20Y5 should be [tex]\$52,000 - \$9,800 = \$42,200, not \$39,200[/tex]. Therefore, the depreciation for 20Y6 should be calculated as follows:

[tex]\[ \text{Year 6 Depreciation} = \$42,200 \times 0.20 = \$8,440 \][/tex]

Now, rounding [tex]\$8,440[/tex] to the nearest cent gives us [tex]\$8,440.00[/tex], which is still less than the remaining depreciable amount. Thus, the corrected depreciation for 20Y6 is [tex]\$8,440.00[/tex].

To summarize, the corrected depreciation for 20Y5 is [tex]\$9,800[/tex], and for 20Y6, it is [tex]\$8,440.00[/tex] when rounded to the nearest cent.

Answer:

$8,721.5

Explanation:

As per the question details provided, we are required to calculate the value of levered firm. Difference between the levered and unlevered firm is that the levered firm compromises of both the equity and debt in its valuation while the unlevered firm only has equity and no debt.

Therefore, the value of levered firm is the sum of the value of unlevered firm and the tax shield available to firm as interest expense on the debt which is tax deductible. The calculation is as follows:

Value of Unlevered Firm (VU) = {Expected Earnings x (1 - Tax Rate)} / Cost of capital

VU = [$1,900 x (1 - .34)]/.16 = $7,837.5

Value of Levered Firm (VL) = VU + Tax Rate (Debt Value)

VL = $7,837.5 + .34 ($2,600) = $8,721.5

Hence, value of the firm is $8,721.5

Answer:

Decrease;increase;frictional

Explanation:

Suppose the world price of steel falls substantially. The demand for labor among steel-producing firms in Pennsylvania will decrease. The demand for labor among automobile-producing firms in Michigan, for which steel is an input, will increase. The temporary unemployment resulting from such sectoral shifts in the economy is best described as frictional unemployment.

The following policies outlined below would help achieve this goal.

1. Improving a widely used job-search website so that it matches workers to job vacancies more effectively.

2. Offering recipients of unemployment insurance benefits a cash bonus if they find a new job within a specified number of weeks.

Answer:

$168,000

Explanation:

Given

Dartmouth Corporation

Contribution format Income Statement

For  the month of June.

Sales (2,800 units) $ 263,200

Variable costs 106,400

Contribution margin 156,800

Fixed costs 135,000

Operating profit $ 21,800

We calculated the sales revenue and the variable costs by dividing the total costs with the number of units and multiplying it with 3000 units to get contribution margin for 3000 units.

Calculated.

Dartmouth Corporation

Contribution format Income Statement

For  the month of June.

Sales ( 3000 units)  ($ 263,200 / 2800) * 3000= $ 282000

Variable costs (106,400  / 2800) * 3000=   $ 114000

Contribution margin  $ 168,000

Fixed costs 135,000

Operating profit $ 33,000

The total contribution margin for Dartmouth Corporation when selling 3,000 units would be $168,000. This is calculated by finding the per-unit contribution margin from the data provided and multiplying it by the new sales level of 3,000 units.

The student is asking how the total contribution margin will change if Dartmouth Corporation sells 3,000 units instead of 2,800. To answer this, we can calculate the per-unit contribution margin from the data provided and then use it to find the total contribution margin at the new sales level of 3,000 units.

First, let's find the per-unit contribution margin:

Contribution Margin per unit = Total Contribution Margin / Number of units sold

Contribution Margin per unit = $156,800 / 2,800 units

Contribution Margin per unit = $56

Now, we can calculate the total contribution margin for 3,000 units:

Total Contribution Margin for 3,000 units = Contribution Margin per unit * Number of units sold

Total Contribution Margin for 3,000 units = $56 * 3,000 units

Total Contribution Margin for 3,000 units = $168,000

Answer:

Ending inventory at cost = $42,098

Explanation:

As per the data given in the question,

                                         Cost price         Retail price

Beginning inventory           $11,000           $19,800

Purchases                         $122,300          $184,200

Net Markups                                               $11,000

Totals                               $133,300           $215,000

Cost of retail ratio = $133,300 ÷ $215,000

= 62%

Retail price total $215,000

Less: Net Markdowns $7,000

Total goods at retail $208,000

Less: Sales $140,100

Ending Inventory at retail $67,900

Ending inventory at cost = $67,900 × 62%

= $42,098

Answer:

1,376,000  and 1.027

Explanation:

According to the scenario, computation of the given data are as follows:-

Price Index = Current Year Cost ÷ Base Year Cost

Year  Current Year Inventory Cost Divided Base Year Inventory Cost Price Index

January 1,2017 $1,000,000 ÷ $1,000,000 1

December 31,2017 $1,419,000 ÷ $1,290,000 1.1

December 31,2018 $1,527,600 ÷ $1,340,000 1.14

Ending Inventory At LIFO Cost = Layer at Base Price Year Inventory × Price Index

Dollar Value LIFO

Year  Layer At Base Price Year Inventory($) Multiple    Price Index Ending Inventory at LIFO Cost($)

2017    

January 1,2017 1,000,000 ×  1 1,000,000

December 31,2017 290,000  × 1.1          319,000

Total                1,290,000   1,319,000

2018    

January 1,2017 1,000,000 × 1 1,000,000

December 31,2017 290,000        × 1.1 319,000

December 31,2018 50,000        ×  1.14 57,000

                       1,340,000   1,376,000

Dollar Value LIFO Inventory                 =  $1,376,000

Internal Price Index = Ending Inventory at LIFO Cost ÷ Layer at Base Year Price

= 1,376,000 ÷ 1,340,000

= 1.027

We simply used the above formulas