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參數(shù)資料

型號(hào)：	MMAD1108R2
廠商：	MOTOROLA INC
元件分類：	二極管(射頻、小信號(hào)、開關(guān)、功率)
英文描述：	0.4 A, 8 ELEMENT, SILICON, SIGNAL DIODE
封裝：	PLASTIC, SO-16
文件頁數(shù)：	25/34頁
文件大小：	311K
代理商：	MMAD1108R2

9–19

Reliability and Quality Assurance

Motorola Small–Signal Transistors, FETs and Diodes Device Data

147

148

149

150

151

152

153

154

39 40

UCL = 152.8

= 150.4

LCL = 148.0

UCL = 7.3

= 3.2

LCL = 0

Figure 4. Example of Process Control Chart Showing Oven Temperature Data

Where D4, D3, and A2 are constants varying by sample size,

with values for sample sizes from 2 to 10 shown in the

following partial table:

n234

56789

3.27

2.57

2.28

2.11

2.00

1.92

1.86

1.82

1.78

0.08

0.14

0.18

0.22

1.88

1.02

0.73

0.58

0.48

0.42

0.37

0.34

0.31

*For sample sizes below 7, the LCLR would technically be a negative number;

in those cases there is no lower control limit; this means that for a subgroup size

6, six ‘‘identical’’ measurements would not be unreasonable.

Control charts are used to monitor the variability of critical

process parameters. The R chart shows basic problems with

piece to piece variability related to the process. The X chart can

often identify changes in people, machines, methods, etc. The

source of the variability can be difficult to find and may require

experimental design techniques to identify assignable causes.

Some general rules have been established to help determine

when a process is OUT–OF–CONTROL. Figure 5 shows a

control chart subdivided into zones A, B, and C corresponding

to 3 sigma, 2 sigma, and 1 sigma limits respectively. In Figures

6 through 9 four of the tests that can be used to identify

excessive variability and the presence of assignable causes

are shown. As familiarity with a given process increases, more

subtle tests may be employed successfully.

Once the variability is identified, the cause of the variability

must be determined. Normally, only a few factors have a

significant impact on the total variability of the process. The

importance of correctly identifying these factors is stressed in

the following example. Suppose a process variability depends

on the variance of five factors A, B, C, D, and E. Each has a

variance of 5, 3, 2, 1, and 0.4, respectively.

Since:

σ tot =

σ A2 + σ B2 + σ C2 + σ D2 + σ E2

σ tot =

52 + 32 + 22 + 12 +(0.4)2 = 6.3

If only D is identified and eliminated, then:

σ tot =

52 + 32 + 22 + (0.4)2 = 6.2

This results in less than 2% total variability improvement. If

B, C, and D were eliminated, then:

σ tot =

52 + (0.4)2 = 5.02

This gives a considerably better improvement of 23%. If

only A is identified and reduced from 5 to 2, then:

σ tot =

22 + 32 + 22 + 12 + (0.4)2 = 4.3

Identifying and improving the variability from 5 to 2 yields a

total variability improvement of nearly 40%.

Most techniques may be employed to identify the primary

assignable cause(s). Out–of–control conditions may be

correlated to documented process changes. The product may

be analyzed in detail using best versus worst part comparisons

or Product Analysis Lab equipment. Multi–variance analysis

can be used to determine the family of variation (positional,

critical, or temporal). Lastly, experiments may be run to test

theoretical or factorial analysis. Whatever method is used,

assignable causes must be identified and eliminated in the

most expeditious manner possible.

After assignable causes have been eliminated, new control

limits are calculated to provide a more challenging variablility

criteria for the process. As yields and variability improve, it may

become more difficult to detect improvements because they

become much smaller. When all assignable causes have been

eliminated and the points remain within control limits for 25

groups, the process is said to in a state of control.

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