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ASA 530 – Audit Sampling and Other Means of Testing
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Michael Cain, FCA
Audit & Accounting Technical Director
Nexia International – Australia and New Zealand
Various means of gathering audit evidence
> 100% examination: this is not a sampling method.
> Selecting specific items: e.g. high value or high risk — this is not a sampling method. Items selected will not necessarily be representative of the population.
> Audit sampling.
ASA 530: Sampling> ASAs do not prescribe any particular
way of determining the sample size or selecting the sample.
> AARF Audit Guide No 1 (available at Institute library) outlines methods for determining the sample size.
Sampling
Stratification
> Stratification: occurs when the auditor divides the population into a series of sub-populations, each of which has an identifying characteristic, such as dollar value.
> Can assist with audit efficiency as it allows the auditor to reduce the sample size by reducing variability, without increasing the sampling risk.
> Can direct auditor’s attention to areas of audit interest, especially risky or material items.
Definition and features
> Audit sampling: the application of an audit procedure to less than 100% of the items within a population to obtain audit evidence about particular characteristics of the population (ASA 530.06.
> Audit sampling is important because it provides information on:• How many items to examine• Which items to select• How sample results are evaluated and
extrapolated to the population in order to tell us something about the population (e.g. level of misstatement).
> ASA 530: Sampling
> Key issue is to select a sample that is representative of the population.
> Remember:
> % coverage is no guarantee of a representative sample.
> The number of items in the population has little effect on the sample size, unless the population is small.
Definition and features
Sampling risk defined
> Sampling risk: the probability that
the auditor has reached an incorrect conclusion because audit sampling
was used rather than 100% examination
(i.e. correctly chosen sample was not
representative of the population).
Non-sampling risk defined
> Non-sampling risk: arises from factors, other than sample size, that cause an auditor to reach an incorrect conclusion, such as the possiblility that:
• The auditor will fail to recognise misstatements included in examined items.
• The auditor will therefore apply a procedure that is not effective in achieving a specific objective.
Characteristic of interest
> When sampling, the auditor identifies a particular characteristic of the population to focus upon.
> For tests of control, the characteristic of interest is the rate of deviation from an internal control policy or procedure.
> For substantive tests, the characteristic of interest is monetary misstatement in the balance.
Statistical sampling defined
> Statistical sampling: any approach to sampling that has the following characteristics:
• Random sample selection.
• Use of probability theory to evaluate sample results, including measurement of sampling risk.
> Major advantage of statistical sampling over non-statistical sampling methods is defensibility, thorough quantification of sampling risk.
> Refer ASA 530.13
Non-statistical sampling
> Non-statistical sampling: sampling approaches that do not have all the characteristics of statistical sampling.
> Major advantage of non-statistical sampling is greater application of audit experience.
> The basic principles and essential procedures identified in ASA 530 apply equally to both statistical and non-statistical sampling.
Plan the sample
1. State the objectives of the audit test
2. Decide whether audit sampling applies
3. Define attributes and deviation conditions
4. Define the population
5. Define the sampling unit
6. Specify the tolerable deviation/misstatement rate
7. Specify allowable risk of overreliance/incorrect acceptance
8. Estimate population deviation/misstatement in the population
9. Determine initial sample size
Select the sample and perform the audit procedures
10. Select the sample
11. Perform the audit procedure
Evaluate the results
12. Generalise from the sample to
the population
13. Analyse the exceptions
14. Decide the acceptability of the population
Planning and designing the sample
> Auditor must consider:
• Objectives of the audit test (usually related to an audit assertion of interest).
• Population from which to sample.
• Possible use of stratification.
• Definition of the sampling unit.
Planning and designing sample for tests of controls
> Auditor should consider:
• Audit objectives (assertions of audit interest).
• Tolerable error — maximum error rate that
would till support control risk assessment.
• Allowable risk of over-reliance — allowable
risk of assessing control risk too low.
• Expected error — amount of error the auditor expects to find in the population.
Defining the audit objective and population
> Once the audit objective is specified, such as reliance on controls or misstatement of account balance, the auditor must consider what conditions would constitute an error.
> The auditor must ensure that the population from which the sample is to be selected is complete and appropriate to the audit objective.
Defining the sampling unit
> Sampling unit is commonly the:
• Transactions or balances making up the account balance; or
• Individual dollars that make up an account balance or class of transactions, commonly referred to as Probability Proportionate to Size Sampling (PPS) or Dollar Unit Sampling (DUS).
Determining sample size
> Sample size is affected by the degree of sampling risk the auditor is willing to accept.
> Auditor's major consideration in determining sample size is whether, given expected results from examining sample, sampling risk will be reduced to an acceptably low level.
Sampling for tests of controls, attribute sampling
> Audit sampling is useful for tests of controls, especially involving inspection of source documentation for specific attributes such as evidence of authorisation (attribute sampling).
> Involves examination of documents for particular attributes related to controls (e.g. authorisation).
> Results of attribute sampling can be used to support or refute an initial assessment of control risk.
Judgemental considering statistical sample sizes
Terminology> Risk of overreliance> Tolerable (error) rate> Expected population deviation rate
Determining the sample size – test of controls
Example using Table 2> 5% risk of overreliance.> No errors are expected (= 0 deviation
rate)> 10% tolerable error rate.
= Sample size of 29 items
Determining the sample size – test of controls
Sample size estimation for attribute samples (alternative method)
> An alternative method is to determine sample size by reference to:
• Appendix, Table 3, for where allowable risk of over-reliance (ARO) is 10% (90% confidence). This ARO is common in practice.
• Appendix, Table 2, for where allowable risk of over-reliance is 5% (95% confidence).
Sampling for substantive tests
> The following matters should be considered:
• Relationship of sample to relevant audit objective (assertion of audit interest)
• Preliminary judgments about materiality levels
• Auditor's allowable risk of incorrect acceptance
• Characteristics of the population
• Use of other substantive procedures directed at same financial report assertion.
Judgemental considering statistical sample sizes
Terminology> Risk of incorrect acceptance> Tolerable error as a % of population> Expected error as a % of tolerable
error
Determining the sample size – substantive tests
Example using Table 1
> Acceptable risk of incorrect acceptance is low.
> Few errors are expected.
> Tolerable error = 10% of population.
= sample size of 23-30 items
Determining the sample size – substantive tests
Judgemental using approximation of a statistical technique
Terminology
> Audit assurance (substantial,
moderate, little).
> Expected error (little/no, or some).
> Individually significant items.
> Tolerable error.
Determining the sample size – substantive tests
Example:
> Recorded amount is $500,000.
> No individually significant amounts.
> Tolerable error = $50,000.
> High degree of assurance required.
> Few errors expected.
Determining the sample size – substantive tests
Formula:
= Population recorded
amount/tolerable error x assurance
(reliability) factor = sample size.
= 500,000/50,000 x 3.0 = 30 items
Determining the sample size – substantive tests
Selecting the sample
> To draw conclusions about population or strata, the sample needs to be typical of characteristics of population or strata.
> Sample needs to be selected without bias so that all sampling units in the population or strata have a chance of selection.
> Common sampling techniques are:• Random selection — random number generation
• Systematic selection
• Haphazard selection — select without conscious bias
Steps in systematic selection
For example, suppose the sample size is 20 and
the number of items in the population is 10,000:
> Step 1: Calculate the sample interval:
> Step 2: Give every item in population chance of selectionby choosing a random number (random start)within range of 1 and sampling interval (in thisexample, 500), e.g. 217.
> Step 3: Continue to add sampling interval to random start,and identify items to be sampled, e.g. item nos. 217, 717, 1217. . . 9217, 9717.
500 20
00010
size Sample
populationin items of No.
Performing the audit procedures
> To ensure conclusions arising from tests on audit samples are appropriate, auditor must perform testing on each item selected.
> If selected item is not appropriate for application of testing procedure, a replacement item can be selected.
> If auditor is unable to perform test on a selected item (e.g. loss of documentation), it is considered to be an error.
Tests of control
> Determine whether exceptions are errors.
> Determine the no. of errors/error rate.
> Compare to tolerable error.
Analyse the exceptions
Evaluation of attribute sample results> Approach in practice is to use sample
deviation rate (SDR) as best estimate of population deviation rate.
> For example, auditor selects 25 items, finds one error => SDR rate is 4%.
> Auditor compares with tolerable deviation rate (TDR). If SDR <= TDR, sample results support auditor’s planned reliance on IC.
> If SDR > TDR, sample results do not support auditor’s planned reliance on IC, auditor will revisit audit plan and reduce reliance on IC and increase substantive testing.
Substantive tests
> Determine any differences.
> Calculate projected error compare
to tolerable error.
Analyse the misstatements
Evaluating sample results> To evaluate sample results, auditor determines the
level of error found in sample and directly projects this error to relevant population. For example: sample 20%, find misstatement of $10,000. Therefore projected error = $50,000 ($10,000/20%).
> Projected error is then compared with tolerable error for the audit procedure to determine if characteristic of interest can be accepted or rejected.
> Auditor should consider both the nature and cause of any errors identified.
Financial report overall
> Summary of audit differences (mandatory requirement).
Decide the acceptability
Dollar-unit sampling > Sample unit is individual dollar units,
not physical units (transactions or balances). A population with $1,000,000 that contains 1,000 physical units or accounts is viewed as a population with 1,000,000 sample units.
> Individual dollar selected is attached to that physical unit or account in which it is contained, which will then be tested.
Advantages of dollar-unit sampling (DUS)
> Directs auditor’s attention to material items. For example, under traditional sampling, debtor A (owing $10,000) and debtor B (owing $1,000) have equal chance of selection. Under DUS, debtor A is ten times more likely to be selected and tested.
> Directs auditor’s attention towards overstatement errors.
> However, a disadvantage is that it directs auditor’s attention away from understatement errors.
Determination of sample size for substantive tests
For convenience, this is usually presented as:
E.g. account balance $1,000,000. Tolerable error $50,000. Expected error is zero and risk of incorrect acceptance is 5% Reliability factor = 3
value book error tolerablefactoryreliabilit
= BV TE
R
=n
TE
RBV x = n
60 00050
3 x 000000 1 Size Sample