Transcript ******* 1

Process Capability
Process Capability

The natural variation of a process should be small enough to
produce products that meet the standards required

A process in statistical control does not necessarily meet the
design specifications

Process capability is a measure of the relationship between the
natural variation of the process and the design specifications
Process Capability Ratio
Cp =
Upper Tolerance Limit (UTL) - Lower Tolerance Limit (LTL)
6s
•
A capable process must have a Cp of at least 1.0
•
Does not look at how well the process is centered in the
specification range
•
Often a target value of Cp = 1.33 is used to allow for offcenter processes
•
Six Sigma quality requires a Cp = 2.0
Process Capability Ratio
In GE insurance claims process, Process mean x = 210.0 minutes
and the process standard deviation is 0.516 minutes. The design
specification to meet customer satisfaction is 210 ± 3 minutes. So
the upper specification (the Upper Tolerance Limit) is 213 minutes
and the lower specification (the Lower Tolerance Limit) is 207
minutes. The manager wants to compute the process capability ratio.
Cp =
Cp =
UTL - LTL
6s
213 - 207
6(.516)
=1.938
Process Capability Ratio
Process Capability Index
The simple Cp measure assumes that the average of the process
variation is at the midpoint of the specification range. Often the
process average is offset from the specification range. In such cases,
one-sided capability indices are required to understand the capability
of the process
Upper one-sided index Cpu =
Lower one-sided index Cpl =
UTL  X
3s
X  LTL
3s
Process Capability Index
Sometimes only the lower of the two one-sided indices for a process
is used to indicate its
capability (Cpk):
Cpk = min( Cpu , Cpl )
•
A capable process must have a Cpk of at least 1.0
•
A capable process is not necessarily in the center of the
specification, but it falls within the specification limit at both
extremes
Process Capability Index
In a process of filling boxes of rice where we measure the weight of
each box, the process average is 210 g and the specification range is
between 198 g and 214 g and the standard deviation of the process is
2 g. Calculate the Process Capability Index.
The process is not capable and therefore cannot meet specifications
Process Capability Index
You are the process improvement manager and have developed a
new machine to cut insoles for the company’s top-of-the-line
running shoes. You are excited because the company’s goal is no
more than 3.4 defects per million and this machine may be the
innovation you need. The insoles cannot be more than + or – 0.001
of an inch from the required thickness. You want to know if you
should replace the existing machine, which has a Cpk of 1.0
New process mean x = .250 inches
Process standard deviation = .0005 inches
Upper Specification Limit = .251 inches
Lower Specification Limit = .249 inches
Process Capability Index
New process mean x = .250 inches
Process standard deviation = .0005 inches
Upper Specification Limit = .251 inches
Lower Specification Limit = .249 inches
Cpk = minimum of
(.251) - .250 .250 - (.249)
,
(3).0005
(3).0005
Both calculations result in
.001
Cpk =
= 0.67
.0015
New machine is NOT
capable
Interpreting Cpk
Cpk = negative number
Cpk = zero
Cpk = between 0 and 1
Cpk = 1
Cpk > 1
LTL
UTL