Production costs

The unit production costs (w) can be separated into fixed and variable costs:

${\displaystyle w={\frac {F_{m}+vx}{x}}\qquad \qquad (3)}$

where

• F_m = manufacturing fixed costs;
• v = variable costs per unit;
• x = production quantity.

The introduction of this separation of w allows for consideration of the behaviour of costs for different levels of production. A linear cost curve is assumed here, divided between the constant (F) and its slope (v). If the modeller has access to the details of non-linear cost curves then w will need to be defined by the appropriate function.

Replacing wx in (equation 2) and making F = F_n + F_m:

${\displaystyle \pi =pq-[F+vx+g0w-g1w]\qquad \qquad (4)}$

Variable-cost elements

Moving on to other extensions of the basic model, the cost elements such as direct materials, direct labour and variable overheads can be included. If a non-linear function is available and thought useful such functions can be substituted for the functions used here.

The material cost of sales = m * µ * q, where

m is the amount of material in one unit of finished goods.

µ is the cost per unit of the raw material.

The labour cost of sales = l λ q, where

• l is the amount of labour hours required to make one unit of finished goods
• λ is the labour cost (rate) per hour.

The variable overhead cost of sales = nq where n is the variable overhead cost per unit.

This is not here subdivided between quantity per finished goods units and cost per unit.

Thus the variable cost v * q can now be elaborated into:

π = pq - [F+(mµ q + l λq + nq)] …………(equation 5)

If the production quantity is required the finished goods stock will need to be added.

In a simple case two materials can be accommodated in the model by simply adding another m * µ. In more realistic situations a matrix and a vector will be necessary (see later).

If material cost of purchases is to be used rather than material cost of production it will be necessary to adjust for material stocks. That is,

mx = md₀ + mb - md₁………… (equation 6)

where

• d = material stock quantity,
• 0 = opening, 1 = closing,
• b = quantity of material purchased
• m = the amount of material in one unit of finished goods
• x = quantity used in production

Depreciation

All depreciation rules can be stated as equations representing their curve over time. The reducing balance method provides one of the more interesting examples.

Using c = cost, t = time, L = life, s = scrap value, Fd = time based depreciation:

Depr/yr = Fd = c (s/c)(t-L)/L * [L(s/c)1/L] …………… (equation 7)

This equation is better known as the rule: Depreciation per year = Last year's written down value multiplied by a constant %

The limits are 0 < t < L, and the scrap value has to be greater than zero. (For zero use 0.1).

Remembering that time-based depreciation is a fixed cost and usage-based depreciation can be a variable cost, depreciation can easily be added into the model (equation 5).

Thus, the profit model becomes:

π = pq - [F + F_d + (mµ + lλ + n + n_d)q].......... (equation 8)

where, nd = usage (as q) based depreciation and π = annual profit.

Stock valuation

In the above, the value of the unit finished goods cost ‘w' was left undefined. There are numerous alternatives to how stock (w) is valued but only two will be compared here.

The marginal versus absorption costing debate, includes the question of the valuation of stock (w).

Should w = v or as (3) w = (Fm + v x)/x.

(i) Under marginal costing: w = v. Inserting in (4),

π = pq- [F + v x + g₀w₀ - g₁ w₁]

Becomes

π = pq- [F + v x + g₀w₀ - g₁ v]

This can be simplified by taking v out and noting, opening stock quantity + production - closing stock quantity = sales quantity (q) so,

π = p q - [F + v q]………….. (equation 9)

Note, v q = variable cost of goods sold.

(ii) Using full (absorption) costing Using (equation 3), where xp = planned production, x1 = period production w = (Fm + v xp)/xp = Fm/xp + v. This can be shown to result in:

π = p q - [F_n + F_m + v q + F_m/x_p * (q-x₁)]………..(equation 10)

Note the strange presence of 'x' in the model. Notice also that the absorption model (equation 10) is the same as the marginal costing model (equation 9) except for the end part:

F/x_p * (q-x₁)

This part represents the fixed costs in stock. This is better seen by remem¬bering q — x= go—g1 so it could be written

F/x_p • (g₀—g₁)

The model form with 'q' and 'x' in place of' g₀ and g₁ allows profits to be calculated when only the sales and production figures are known.

A spreadsheet could be prepared for a company with increasing then decreasing levels of sales and constant production. It could have another column showing profit under increasing sales and constant production. Thus the effects of carrying fixed costs in stock can be simulated. Such modelling thus provides a very useful tool in the marginal versus full costing debate.

Modelling for losses

One way of modeling for losses is to use:

• Fixed losses, (quantity) = δf,
• Variable losses (%) = δv,
• Material losses = mδ,
• Production losses = pδ

The model, with all these losses together will look like,

π = v q – [F + µ * mδf + {mµ(1 + mδv) + lλ+n) * (1+ pδ* (q +pδf)]........ (equation 11)

Note that labour and variable overhead losses could also have been included.

Multi-products

So far the model has assumed very few products and/or cost elements. As many firms are multi-product the model they use must be able to handle this problem. Whilst the mathematics here is straightforward the accounting problems introduced are enormous: the cost allocation problem being a good example. Other examples include calculation of break-even points, productivity measures and the optimisation of limited resources. Here only the mechanics of building a multi-dimension model will be outlined.

If a firm sells two products (a and b) then the profit model (equation 9),

π = pq —(F +vq) becomes

π = (pa *qa +pb *qb) - [F + va*qa + vb *qb]

All fixed costs have been combined in F

Therefore, for multiple products

π = Σ(pq) - [F + Σ(vq)].... (equation 12)

Where Σ = the sum of. Which can be drafted as a vector or matrix in a spreadsheet

or

π = Σpq - [F + Σ(Σmμ +Σlλ + Σn)q]..... (equation 13)

Variances

The profit model may represent actual data (c), planned data (p)or standard data (s) which is the actual sales quantities at the planned costs.

The actual data model will be (using equation 8):

π = p_c*q_c - [F_c + (mµ_c + lλ_c + n_c)q_c]

The planned data model will be (using equation 8):

π = p_p*q_p - [F_p + (mµ_p + lλ_p + n_p)q_p]

The standard data model will be (using equation 8):

π = p_p*q_c - [F_p + (mµ_p + lλ_p + n_p)q_c]

Operating variances are obtained by subtracting the actual model from the standard model.

Learning Curve Model

It is possible to add non linear cost curves to the Profit model. For example, if with learning, the labour time per unit will decrease exponentially over time as more product is made, then the time per unit is:

l = r * q^−b

where r = average time. b = learning rate. q = quantity.

Inserting into equation 8

π = pq - [F + (mµ + rq^−bλ + n)q]

This equation is best solved by trial and error, the Newton Raphson method or graphing. Like depreciation within the model, the adjustment for learning does provide a form of non-linear sub-modelling.

Percentage Change Model

Rather than the variable be absolute amounts, they might be percentage changes. This represents a major change in approach from the model above. The model is often used in the 'now that ... (say) the cost of labour has gone up by 10%' format. If a model can be developed that only uses such percentage changes then the cost of collecting absolute quantities will be saved.^[5]

The notation used below is of attaching a % sign to variables to indicate the change of that variable, for example, p% = 0.10 if the selling price is assumed to change by 10%,

Let x = q and C = contribution

Starting with the absolute form of the contribution model (equation (9) rearranged):

π + F = C = (p — v)q.

The increase in the contribution which results from an increase in p, v and/or q can be calculated thus:

C(l + C%) = [p(l+p%)- v(l + v%)]q(l+q%)

rearranging and using α = (p — v)/p,

C% = ((l+q%)/α)[p%-(l - α)v%]+q%...... (equation 18)

This model might look messy but it is very powerful. It makes very few demands on data, especially if some of the variables do not change. It is possible to develop most of the models presented above in this percentage change format.