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Acceptance Sampling

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The purpose of acceptance sampling is to sentence lots (accept or reject) rather ... The Operating Characteristic Curve is typically used to represent the four ... – PowerPoint PPT presentation

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Title: Acceptance Sampling


1
Acceptance Sampling
  • Acceptance sampling is a method used to accept or
    reject product based on a random sample of the
    product.
  • The purpose of acceptance sampling is to sentence
    lots (accept or reject) rather than to estimate
    the quality of a lot.
  • Acceptance sampling plans do not improve quality.
    The nature of sampling is such that acceptance
    sampling will accept some lots and reject others
    even though they are of the same quality.
  • The most effective use of acceptance sampling is
    as an auditing tool to help ensure that the
    output of a process meets requirements.

2
  • As mentioned acceptance sampling can reject
    good lots and accept bad lots. More
    formally
  • Producers risk refers to the probability of
    rejecting a good lot. In order to calculate this
    probability there must be a numerical definition
    as to what constitutes good
  • AQL (Acceptable Quality Level) - the numerical
    definition of a good lot. The ANSI/ASQC standard
    describes AQL as the maximum percentage or
    proportion of nonconforming items or number of
    nonconformities in a batch that can be considered
    satisfactory as a process average
  • Consumers Risk refers to the probability of
    accepting a bad lot where
  • LTPD (Lot Tolerance Percent Defective) - the
    numerical definition of a bad lot described by
    the ANSI/ASQC standard as the percentage or
    proportion of nonconforming items or
    noncomformities in a batch for which the customer
    wishes the probability of acceptance to be a
    specified low value.

3
  • The Operating Characteristic Curve is typically
    used to represent the four parameters (Producers
    Risk, Consumers Risk, AQL and LTPD) of the
    sampling plan as shown below where the P on the x
    axis represents the percent defective in the lot
  • Note if the sample is less than 20 units the
    binomial distribution is used to build the OC
    Curve otherwise the Poisson distribution is used.

4
Designing Sampling Plans
  • Operationally, three values need to be determined
    before a sampling plan can be implemented (for
    single sampling plans)
  • N the number of units in the lot
  • n the number of units in the sample
  • c the maximum number of nonconforming units in
    the sample for which the lot will be accepted.
  • While there is not a straightforward way of
    determining these values directly given desired
    values of the parameters, tables have been
    developed. Below is an excerpt of one of these
    tables.

5
Three alternatives for specifying sampling plans
  • Producers Risk and AQL specified
  • Consumers Risk and LTPD specified
  • All four parameters specified
  • For the first two cases we simply choose the
    acceptance number and divide the appropriate
    column by the associated parameter to get the
    sample size.
  • Example 1 Given a producers risk of .05 and an
    AQL of .015 determine a sampling plan
  • c 1 n .355/.015 24
  • c 4 n 1.97/.015 131
  • Example 2 Given a consumers risk of .1 and a
    LTPD of .08 determine a sampling plan
  • c 0 n 2.334/.08 29
  • c 5 n 9.274/.08 116
  • Note you can check these with the OC curve
    posted on my web site

6
All four parameters specified
  • When all four parameters are specified we must
    first find a value close to the ratio LTPD/AQL in
    the table. Then values of n and c are found.
  • Example Given producers risk of .05, consumers
    risk of .1, LTPD 4.5, and AQL of 1 find a
    sampling plan.
  • Since 4.5/1 4.5 is between c 3 and c 4.
    Using the n(AQL) column the sample sizes
    suggested are 137 and 197 respectively. Note
    using this column will ensure a producers risk of
    .05. Using the n(LTPD) column will ensure a
    consumers risk of .1

7
Double Sampling
  • In an effort to reduce the amount of inspection
    double (or multiple) sampling is used. Whether
    or not the sampling effort will be reduced
    depends on the defective proportions of incoming
    lots. Typically, four parameters are specified
  • n1 number of units in the first sample
  • c1 acceptance number for the first sample
  • n2 number of units in the second sample
  • c2 acceptance number for both samples

8
Procedure
  • A double sampling plan proceeds as follows
  • A random sample of size n1 is drawn from the
    lot.
  • If the number of defective units (say d1 ) ? c1
    the lot is accepted.
  • If d1? c2 the lot is rejected.
  • If neither of these conditions are satisfied a
    second sample of size n2 is drawn from the lot.
  • If the number of defectives in the combined
    samples (d1 d2) gt c2 the lot is rejected. If
    not the lot is accepted.

9
Example
  • Consider a double sampling plan with n1 50 c1
    1 n2 100 c2 3. What is the probability
    of accepting a lot with 5 defective?
  • The probability of accepting the lot, say Pa, is
    the sum of the probabilities of accepting the lot
    after the first and second samples (say P1 and
    P2)
  • To calculate P1 we first must determine the
    expected number defective in the sample (50.05)
  • we can then use the Poisson function to
    determine the probability of finding 1 or fewer
    defects in the sample, e.g., Poisson(1,2.5,true)
    .287
  • To calculate P2 we need to determine first the
    scenarios that would lead to requiring a second
    sample. Then for each scenario we must determine
    the probability of acceptance. P2 will then be
    the some of the probability of acceptance for
    each scenario.

10
  • Example continued
  • For this example, there are only two possible
    scenarios that would lead to requiring a second
    sample
  • Scenario 1 2 nonconforming items in the first
    sample
  • Scenario2 3 nonconforming items in the first
    sample.
  • The probability associated with these two
    scenarios is found as follows
  • P(scenario 1) Poisson(2,2.5,false) .257
  • P(scenario 2) Poisson(3,2.5,false) .214
  • Under scenario 1 the lot will be accepted if
    there are either 1 or 0 nonconforming items in
    the second sample. The expected number of
    nonconforming items in the second sample .05(100)
    5
  • the probability is then Poisson(1,5,true) .04
  • therefore the probability of acceptance under
    scenario 1 is (.257)(.04) .01
  • Under scenario 2 we will accept the lot only if
    there are 0 nonconforming items in the second
    sample, i.e., Poisson(0,5,false) .007
  • therefore the probability of acceptance under
    scenario 2 is (.214)(.007) .0015
  • so the probability of acceptance on the second
    sample is .01 .0015 .0115
  • So the overall probability of acceptance is
    (probability of acceptance on first sample
    probability of accepting after 2 samples) .287
    .0115 .299

11
OC curve for double sampling
12
Average Sample Number
  • Since the goal of double sampling is to reduce
    the inspection effort, the average number of
    units inspected is of interest. This is easily
    calculated as follows
  • Let PI the probability that a lot disposition
    decision is made on the first sample, i.e.,
    (probability that the lot is rejected on the
    first sample probability that the lot is
    accepted on the first sample)
  • Then the average number of items is
  • n1(PI) (n1 n2)(1 - PI)
  • n1 n2(1 - PI)

13
The average sample number curve can be derived
from the data on the OC chart
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