Software Quality Engineering CS410 - PowerPoint PPT Presentation

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Software Quality Engineering CS410

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Title: Software Quality Engineering CS410


1
Software Quality EngineeringCS410
  • Class 5
  • Seven Basic Quality Tools

2
Seven Basic Quality Tools
  • Promoted by Ishikawa (1989)
  • Set of statistical tools for quality control
  • Can be used to analyze software metrics
  • Most applicable to Project Managers
  • Statistical process control for SW development is
    more challenging than traditional manufacturing
  • Tools can have a positive influence on quality
    improvement and decision making

3
Seven Basic Quality Tools
  • Seven Tools
  • 1. Checklist (or Check Sheet)
  • 2. Pareto Diagram
  • 3. Histogram
  • 4. Scatter Diagram
  • 5. Run Chart
  • 6. Control Chart
  • 7. Cause-Effect Diagram
  • Figure 5.1 p. 130

4
Checklist
  • A paper (or softcopy) form used for collecting
    and arranging data so that it can be easily used
    later
  • Also a method for ensuring that key points and
    tasks are addressed, or performed, at the correct
    times
  • Also a method to assist in knowing when a
    particular task is complete
  • Can be implemented as an expert system to guide
    process and give advise

5
Checklist
  • Checklist examples
  • Common Error Checklist - developed as part of
    DPP, used at stage kickoff to review common
    errors at that stage
  • Process Checklists
  • Program Fix Checklists - ensure that all the
    required steps for completing a fix have been
    done (example fig. 5.2 pp132-133)
  • Code Complete Checklists - ensure that all coding
    standards and procedures have been followed

6
Pareto Diagram
  • Pareto Principle (80/20 rule)
  • 80 of the defects are contained in 20 of the
    modules and components
  • 20 of a particular defect type cause 80 of the
    customer calls
  • Pareto analysis helps identify focus areas that
    cause most of the problems
  • Pareto Analysis can be charted as frequencies in
    descending rank order with a cumulative
    percentage line (fig 5.3 p. 134 and fig. 5.4 p.
    136)

7
Histogram
  • A graphic representation of frequency
    distribution
  • Should convey complete information at a glance
  • Examples
  • Defect distributions by Sev level (fig. 5.5(A) p.
    137)
  • Defect distribution by days open (fig. 5.5(B) p.
    137)
  • Profile of Customer Satisfaction (fig. 5.6 p.
    137)

8
Run Charts
  • A real-time statement of quality and/or workload.
  • Defect arrival rates weekly
  • Defect backlog
  • Delinquent fixes
  • Should include target for comparison
  • Can track significant events, and show results
  • Figure 5.7 p. 138

9
Run Charts
  • Good tool for project and schedule management.
  • Run Chart can display the typical S Curve
  • Tracks actual vs. planned over time
  • Completion of design review
  • Completion of code inspection
  • Completion of code integration
  • Completion of component test
  • Completion of system test
  • etc.

10
Scatter Diagrams
  • Usually relates to investigative work (I.e.
    investigating relationships)
  • Requires precise data
  • Works well for correlation analysis
  • For example Code complexity vs. Defect Rate (fig
    5.9 p. 140)
  • Shows positive correlation
  • Can be used as a predictor
  • Can be used as a tool to reduce defect rate (by
    reducing code complexity)

11
Scatter Diagrams
  • Can also be used for identifying/prioritizing
    areas requiring action items
  • For example Defects rates for reused components
    in multiple projects (fig. 5.10 p. 141, and fig.
    5.11 p. 142)
  • Helps identify chronic problem components
  • Helps focus action items on greatest payback

12
Control Chart
  • A tool used in Statistical Process Control (SPC)
  • Can be used real-time for improving consistency
    and stability
  • A tool for measuring Process Capability
  • Process Capability - inherent variation in the
    process in relation to the specification limits
  • The smaller the process variation the better the
    processs capability
  • Process Capability is a difficult thing to
    estimate in software projects, however Control
    Charts are a useful quality management tool.

13
Control Chart
  • Types of control charts
  • X-bar - sample averages
  • S chart - standard deviations
  • Median chart - individuals
  • P chart - proportion nonconforming
  • NP chart - number nonconforming
  • C chart - number nonconformities
  • U chart - nonconformities per unit
  • Most appropriate to SW Engineering
  • P chart - when percentages are involved
  • U chart - when defect rates are involved

14
Control Chart
  • Control limits must be calculated and included on
    the chart
  • Different ways of calculating control limits
    exists.
  • Historical data
  • Weighted averages
  • Standard Deviations
  • SW metrics that can be control charted
  • Defects per component/KLOC (fig. 5.12 p. 146)
  • Phase effectiveness (fig. 5.14 p. 147)
  • Backlog Management Index

15
Cause-Effect Diagram
  • Also known as a Fishbone Diagram
  • Not widely used in SW development
  • Graphically relates causes and effects
  • Effect can be a positive or negative
    characteristic
  • Examples
  • Register Allocation Defects (negative) fig. 5.15
    p. 148
  • Effective Inspections (positive) fig 5.16 p. 149

16
Seven Basic Quality Tools Summary
  • Statistical tools (scientific methods) are used
    heavily in manufacturing, and are slowly being
    incorporated into SW engineering.
  • Some tools can be used together effectively
  • Pareto Diagrams, Cause-Effect Diagrams, and
    Scatter Diagrams, can be used together to
    identify dominant problems and their root causes.
  • Control Charts can be used to monitor process
    stability.

17
Seven Basic Quality Tools Summary
  • Keys to a tools value
  • Consistent use
  • Pervasive use
  • Automation
  • Integration
  • As a tool for process improvement

18
Seven Basic Quality Tools Summary
  • Ishikawas Tools a.k.a. Seven Old Tools
  • Other tools - Seven New Tools
  • Affinity Diagram
  • Relations Diagram
  • Tree Diagram
  • Metric Chart
  • Matrix Data Analysis Chart
  • Process Decision Program Chart
  • Arrow Diagram
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